Handbook of Hydrocolloids

Handbook of hydrocolloids Second edition Edited by G. O. Phillips and P. A. Williams Published by Woodhead Publishing ...

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Handbook of hydrocolloids Second edition Edited by G. O. Phillips and P. A. Williams

Published by Woodhead Publishing Limited, Abington Hall, Granta Park, Great Abington, Cambridge CB21 6AH, UK www.woodheadpublishing.com Woodhead Publishing India Private Limited, G-2, Vardaan House, 7/28 Ansari Road, Daryaganj, New Delhi ± 110002, India Published in North America by CRC Press LLC, 6000 Broken Sound Parkway, NW, Suite 300, Boca Raton, FL 33487, USA First published 2009, Woodhead Publishing Limited and CRC Press LLC ß 2009, Woodhead Publishing Limited The authors have asserted their moral rights. This book contains information obtained from authentic and highly regarded sources. Reprinted material is quoted with permission, and sources are indicated. Reasonable efforts have been made to publish reliable data and information, but the authors and the publishers cannot assume responsibility for the validity of all materials. Neither the authors nor the publishers, nor anyone else associated with this publication, shall be liable for any loss, damage or liability directly or indirectly caused or alleged to be caused by this book. Neither this book nor any part may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, microfilming and recording, or by any information storage or retrieval system, without permission in writing from Woodhead Publishing Limited. The consent of Woodhead Publishing Limited does not extend to copying for general distribution, for promotion, for creating new works, or for resale. Specific permission must be obtained in writing from Woodhead Publishing Limited for such copying. Trademark notice: Product or corporate names may be trademarks or registered trademarks, and are used only for identification and explanation, without intent to infringe. British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library. Library of Congress Cataloging in Publication Data A catalog record for this book is available from the Library of Congress. Woodhead Publishing Limited ISBN 978-1-84569-414-2 (book) Woodhead Publishing Limited ISBN 978-1-84569-587-3 (e-book) CRC Press ISBN 978-1-4398-0820-7 CRC Press order number: N10074 The publishers' policy is to use permanent paper from mills that operate a sustainable forestry policy, and which has been manufactured from pulp which is processed using acid-free and elemental chlorine-free practices. Furthermore, the publishers ensure that the text paper and cover board used have met acceptable environmental accreditation standards. Typeset by Godiva Publishing Services Limited, Coventry, West Midlands, UK Printed by TJ International Limited, Padstow, Cornwall, UK

Preface

The first edition of the Handbook of Hydrocolloids was published in 2000 and was exceptionally well received. It has been used as the substantive reference book in the subject. It was not meant to be a textbook, but a convenient reference to provide the relevant information readily and at the same time authoritatively. The chapters were all written by top specialists in their fields. Since the year 2000, the subject has moved on with remarkable speed. The dominant industrial influence has been the succession of mergers and acquisitions. The names of very many of the companies which participated over the years have either disappeared or now form part of bigger amalgamations. The specialist single product producer has given way to the global multi-ingredient suppliers. Now it is the global giants who dominate the ever increasing technological industry. While such progress is, I suppose, inevitable, it has taken its toll on individuals who are finding it increasingly difficult to keep pace with changing materials, technologies, loyalties and names. Much corporate memory has been lost in these frantic changes. In this Second Edition we have kept this in mind and now provide a single and reliable reference volume where hydrocolloids structure, functionality, synergistic behaviour, applications and regulatory aspects are brought together. These are the new improvements we have taken to ensure that we fully meet the core and developing hydrocolloid areas: · First, all chapters in the first edition were re-visited and, where necessary, these chapters were up-dated. · Now there is a much greater emphasis on the protein hydrocolloids. New chapters have therefore been included on egg proteins and vegetable proteins (soybean, pea, wheat, and other related protein isolates) and the more recent information about fish gelatin has been added.

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Preface

· We have increased the coverage of microbial polysaccharides, with a new chapter on the newly emerging microbial polysaccharides such as pullulan, scleroglucan, elsinan, levan, alternan, etc., which are now moving out of the scientific novelty area into practical use. · The developing role of the exudate gums has been recognized, with a new chapter on gum ghatti included. This old gum is rapidly making a resurgence, particularly as a clean label natural emulsifier and adhesive. New sections have been added also on mesquite gum and larchwood arabinogalactans. · Protein-hydrocolloid complexes are now extensively studied in order to gain synergy from both components. A new chapter is, therefore, included to chart these new developments. · There is a new chapter on the function of hydrocolloids as emulsifiers and the factors which determine the stabilization and long-term stability of the emulsions. · The customer is now not only demanding convenience but also healthier foods. The functional foods, or nutraceuticals, have now come of age. Sales of such foods have risen exponentially. Obesity, calorific value, fat replacement, glycaemic index and dietary fibre are at the forefront of the medical and political platform. A new chapter has been added to acknowledge this vital new emphasis in using hydrocolloids in foods. Information has also been added about health aspects where relevant to other updated chapters. · There is a complete new chapter on the extraction, structure, analysis, physical chemical properties, technology, applications and health benefits of arabinoxylans. Without question it can prove rewarding to become well aquainted with the hydrocolloids described in this book. The tumultuous growth associated with the revolution already referred to is both confusing and perplexing. The choice of hydrocolloids is larger but fewer and fewer companies are in a position to provide them because, as they become larger, each company tries to provide the widest possible range of hydrocolloids. Due to the rash of recent mergers, a single company can now provide galactomannans, guar and locust bean gum, pectins, alginates, carrageenans, xanthan and gelatin. Added to this, the technological developments are leading to the crossing of traditional boundaries. Carrageenan is challenging the functionality of gelatin. Starch is trying to replicate the behaviour of gum arabic, and so on. Therefore, there is no substitute for studying the hydrocolloids individually and objectively, in order to avoid this over-concentration of expertise and supply. We hope that this handbook in its new and enlarged form will assist in this respect. We welcome any comments or suggestions. We certainly hope that it will assist all levels of reader, from the student to the experienced scientist, to understand this rapidly growing, enjoyable yet challenging subject. Glyn O. Phillips and Peter A. Williams Phillips Hydrocolloids Research Ltd and the Centre for Water Soluble Polymers, Glyndwr University

Contributor contact details

(* = main contact)

Chapters 1 and 11 P. A. Williams Glyndwr University Plas Coch Mold Road Wrexham LL11 2AW UK E-mail: [email protected] G. O. Phillips Phillips Hydrocolloids Research Ltd 45 Old Bond Street London W15 4AQ E-mail: [email protected]

Chapter 2 E. Dickinson Procter Department of Food Science University of Leeds Leeds LS2 9JT UK E-mail: [email protected]

Chapter 3 C. A. Edwards* and A. L. Garcia Human Nutrition Section Division of Developmental Medicine University of Glasgow Yorkhill Hospitals Glasgow G3 8SJ UK E-mail: [email protected]

Chapter 4 R. ArmiseÂn* Hispanagar S. A. R & D Director (Retired) Independent Chemistry Consultant Calle Sierra Ovejero 8 Pozuelo de AlarcoÂn 28224 Madrid Spain E-mail: armisen.consulting@ armisen.e.telefonica.net

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Contributors

F. Galatas Hispanagar S.A. Calle Pedro de Valdivia 34 28006 Madrid Spain

Chapter 5 P. Taggart National Starch Food Innovation Prestbury Court Greencourts Business Park 333 Styal Road Manchester M22 5LW UK E-mail: [email protected] J.R. Mitchell* Division of Food Sciences Sutton Bonnington Campus University of Nottingham Loughborough LE12 5RD UK E-mail: [email protected]

Chapter 6 I. J. Haug* and K. I. Draget Norwegian University of Science and Technology (NTNU) N-7491 Trondheim Norway E-mail: [email protected] [email protected]

Chapter 7 Alan Imeson FMC Biopolymer 12 Langley Close Epsom Surrey KT18 6HG UK E-mail: [email protected]

Chapters 8 and 9 Graham Sworn Danisco France SAS 20 rue Brunel 75017 Paris France E-mail: [email protected]

Chapter 10 W. Wielinga Hinterdorfstrasse 41 8274-TaÈgerwilen Switzerland E-mail: [email protected]

Chapter 12 Hans-Ulrich Endreû* Herbstreith & Fox KG Pektin-Fabrik NeuenbuÈrg 75305 NeuenbuÈrg Germany E-mail: [email protected] Steen Hoejgaard Christensen CP Kelco ApS 4621 Lille Skensved Germany E-mail: [email protected]

Contributors

Chapter 13 J. O'Regan, M. P. Ennis and D. M. Mulvihill* Department of Food & Nutritional Sciences National University of Ireland Cork University College Cork Cork Ireland E-mail: [email protected]

Chapter 14 M. Anton* INRA Nantes UniteÂ 1268 BiopolymeÁres Interactions Assemblages BP 71627 44316 Nantes cedex 3 France E-mail: [email protected] F. Nau and V. Lechevalier DeÂpartement AgroAlimentaire ± Agrocampus Ouest UMR INRA Science et Technologie du Lait et de l'Oeuf 65 rue de Saint Brieuc CS 84215 35042 Rennes cedex France E-mail: [email protected] [email protected]

Chapter 15 S. GonzaÂlez-PeÂrez* and J. B. Arellano Institute of Natural Resources and Agrobiology Consejo Superior de Investigaciones CientõÂficas (IRNASA-CSIC) Cordel de Merinas 40-52 37008 Salamanca Spain

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E-mail: [email protected] [email protected]

Chapter 16 C. Schmitt* Department of Food Science and Technology NestleÂ Research Center Vers-chez-les-Blanc CH-1000 Lausanne 26 Switzerland E-mail: [email protected] L. Aberkane Laboratoire d'IngeÂnierie des BiomoleÂcules INPL-ENSAIA 2 Avenue de la ForeÃt de Haye F-54505 Vandoeuvre-leÁs-Nancy cedex 5 France C. Sanchez Laboratoire Biocatalyse BioproceÂdeÂs INPL-ENSAIA 2 Avenue de la ForeÃt de Haye F-54505 Vandoeuvre-leÁs-Nancy cedex 5 France

Chapter 17 Saphwan Al-Assaf,* G.O. Phillips and V. Amar Phillips Hydrocolloids Research Centre Glyndwr University, Wrexham Mold Road Wrexham LL11 2AW UK E-mail: [email protected] [email protected]

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Contributors

Chapter 18

Chapter 19

Y. LoÂpez-Franco Laboratory of Biopolymers Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo A.C. P.O. Box 1735 Hermosillo Sonora 83000 Mexico

K. Nishinari* and M. Takemasa Department of Food & Nutrition Faculty of Human Life Science Osaka City University Sumiyoshi Osaka 558-0022 Japan E-mail: [email protected]

I. Higuera-Ciapara Laboratory of Natural Polymers Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo A.C. P.O. Box 284 Guaymas Sonora 85440 Mexico F. M. Goycoolea* Department of Pharmacy and Pharmaceutical Technology Universidad de Santiago de Compostela Campus Sur s/n A CorunÄa 15782 Spain E-mail: [email protected] and Laboratory of Biopolymers Centro de Investigacion en Alimentacion y Desarrollo, A. C. P.O. Box 1735 Hermosillo Sonora 83000 Mexico E-mail: [email protected] Weiping Wang Andi-Johnson Konjac Co Ltd. 1-504 Long Spring Gardens 118 Yang Bridge West Road Fuzhou China 350002 E-mail: [email protected]

and Phillips Hydrocolloid Research Centre/Glyndwr University Plas Coch Mold Road Wrexham LL11 2AW UK and Department of Polymer Science & Engineering Shanghai Jiao Tong University Shanghai 200240 People's Republic of China K. Yamatoya and M. Shirakawa Dainippon-Sumitomo Pharma Co. Ltd 1-5-51 Eble, Fukushima Osaka 553-0001 Japan

Chapter 20 K. Nishinari* Department of Food & Nutrition Faculty of Human Life Science Osaka City University Sumiyoshi Osaka 558-0022 Japan E-mail: [email protected]

Contributors and Phillips Hydrocolloid Research Centre/Glyndwr University Plas Coch Mold Road Wrexham LL11 2AW UK and Department of Polymer Science & Engineering Shanghai Jiao Tong University Shanghai 200240 People's Republic of China H. Zhang Department of Polymer Science & Engineering Shanghai Jiao Tong University Shanghai 200240 People's Republic of China T. Funami Hydrocolloid Laboratory San-Ei Gen F.F.I. Inc. Toyonaka Osaka 561-8588 Japan

T. Khan Department of Pharmaceutical Science COMSATS Institute of Information Technology University Road Post Code 22060 Abbottabad NWFP Pakistan E-mail: [email protected]

Chapter 22 D. G. Stevenson* National Starch Bridgewater, NJ 08807 USA E-mail: [email protected] G. E. Inglett National Center for Agricultural Utilization Research (NCAUR) Agricultural Research Center USDA Peoria, IL 61604 USA

Chapter 23 Chapter 21 J. K. Park Department of Chemical Engineering Kyungpook National University Sankyuk-dong 1370 Buk-ku Daegu 701-702 Korea E-mail: [email protected]

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M. S. Izydorczyk Grain Research Laboratory Canadian Grain Commission 14040303 Main Street Winnipeg, MB Canada R3C 3G8 E-mail: marta.izydorczyk@ grainscanada.gc.ca

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Contributors

Chapter 24 H. Maeda Protein and Food Ingredients Division Soy Protein Processed Foods Company Fuji Oil Co., Ltd 1 Sumiyoshi-cho Izumisano-shi Osaka 598-8540 Japan E-mail: [email protected] A. Nakamura Research and Development Headquarters Food Science Research Institute Fuji Oil Co., Ltd. 4-3 Kinunodai Tsukubamirai-shi Ibaraki-Pref. 300-2497 Japan E-mail: [email protected]

Chapter 25 J. C. F. Murray London UK E-mail: [email protected]

Chapter 26 J. K. Park Department of Chemical Engineering Kyungpook National University Sankyuk-dong 1370 Buk-ku Daegu 701-702 Korea E-mail: [email protected]

J. Y. Jung Search & Analysis Team 2 Korea Institute of Patent Information (KIPS) 647-9 Yeoksam-dong Gangnam-gu Seoul Korea 135-980 E-mail: [email protected] or [email protected] T. Khan Department of Pharmaceutical Science COMSATS Institute of Information Technology University Road Post Code 22060 Abbottabad NWFP Pakistan E.mail: [email protected]

Chapter 27 G. R. Krawczyk,* A. Venables and D. Tuason FMC BioPolymer PO Box 8 Princeton, NJ 08543 USA E-mail: [email protected] [email protected] [email protected]

Contributors

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Chapter 28

Chapter 31

A. Nussinovitch The Hebrew University of Jerusalem Institute of Biochemistry Food Science and Nutrition The Robert H. Smith Faculty of Agriculture, Food and Environment P.O. Box 12 Rehovot 76100 Israel E-mail: [email protected]

R. A. A. Muzzarelli Muzzarelli Consulting Via Volterra 7 IT-60123 Ancona Italy E-mail: [email protected]

Chapter 29 K. I. Draget Department of Biotechnology Norwegian University of Science and Technology (NTNU) N-7491 Trondheim Norway E-mail: [email protected]

Chapter 30 D. Meyer Sensus PO Box 1308 4700 BH Roosendaal The Netherlands E-mail: [email protected] J.-P. Blaauwhoed Cosun Food Technology Centre PO Box 1308 4700 BH Roosendaal The Netherlands

and R. A. A. Muzzarelli and C. Muzzarelli Institute of Biochemistry University of Ancona Via Ranieri 67 IT-60100 Ancona Italy

Chapter 32 S. Takigami Center for Material Research by Instrumental Analysis Gunma University 1-5-1 Tenjincho Kiryu-shi Gunma 376-8515 Japan E-mail: [email protected]

Contents

Contributor contact details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

xv

Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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1

Introduction to food hydrocolloids . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P. A. Williams and G. O. Phillips, Glyndwr University, UK 1.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.2 Regulatory aspects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.3 Thickening characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4 Viscoelasticity and gelation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.5 Synergistic combinations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.6 Hydrocolloid fibres . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.7 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.8 Bibliography . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2

Hydrocolloids and emulsion stability . . . . . . . . . . . . . . . . . . . . . . . . . . . . E. Dickinson, University of Leeds, UK 2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2 Principles of emulsion stability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.3 Effect of non-adsorbing hydrocolloids on emulsion stability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.4 Effect of adsorbing hydrocolloids on emulsion stability . . . . . 2.5 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.6 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1 1 5 8 14 18 19 21 22 23 23 26 35 42 46 47

vi

Contents 3 The health aspects of hydrocolloids . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C. A. Edwards and A. L. Garcia, University of Glasgow, UK 3.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2 Hydrocolloids and non-digestible carbohydrates in food . . . . . 3.3 Effects on metabolism and health . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.4 Clinical nutrition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.5 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Agar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . R. ArmiseÂn and F. Galatas, Hispanagar S. A., Spain 4.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2 Agar manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3 Chemical structure of agar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4 Agar gelation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5 Agar applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.7 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5 Starch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P. Taggart, National Starch Food Innovation, UK and J.R. Mitchell, Division of Food Sciences, University of Nottingham, UK 5.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.4 Modifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.6 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7 Regulatory status: European label declarations . . . . . . . . . . . . . . . 5.8 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Gelatin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I. J. Haug and K. I. Draget, Norwegian University of Science and Technology (NTNU), Norway 6.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2 Manufacturing gelatin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3 Regulations, technical data and standard quality test methods 6.4 Chemical composition and physical properties of collagens and gelatins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.5 Gelatin derivatives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.6 Applications of gelatin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.7 Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.8 References and further reading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

50 50 51 55 69 70 71 82 83 86 89 91 96 104 105 108 108 109 110 115 121 125 137 140 142 142 143 147 149 157 158 162 162

Contents 7 Carrageenan and furcellaran . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A. P. Imeson, FMC Biopolymer, UK 7.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.4 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.5 Physical properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.6 Food applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.7 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.8 Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Xanthan gum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . G. Sworn, Danisco France SAS, France 8.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.5 Applications in food products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.7 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.8 Sources of further information and advice . . . . . . . . . . . . . . . . . . . 8.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Gellan gum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . G. Sworn, Danisco France SAS, France 9.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.5 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.7 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.8 Sources of further information and advice . . . . . . . . . . . . . . . . . . . 9.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Galactomannans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . W. C. Wielinga, retired in 2000 from Meyhall AG, Kreuzlingen, Switzerland, which was subsequently acquired by Danisco A/S 10.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.2 Raw materials and structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

vii 164 164 165 167 169 170 177 183 183 184 186 186 187 187 188 195 201 201 202 202 204 204 205 205 206 213 225 225 226 226 228 229 229 237 243 249 249

viii

Contents 10.7 10.8

Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

250 250

11 Gum arabic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P. A. Williams and G. O. Phillips, Glyndwr University, UK 11.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2 Supply and market trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4 Regulatory aspects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6 Properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.8 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

252

12 Pectins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . H.-U. Endreû, Herbstreith & Fox KG Pektin-Fabrik NeuenbuÈrg, Germany and S. H. Christensen, CP Kelco ApS, Germany 12.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.3 The chemical nature of pectin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.4 Commercial pectin: properties and function . . . . . . . . . . . . . . . . . . 12.5 Nutritional and health aspects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.7 Legal status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.8 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Milk proteins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . J. O. Regan, M. P. Ennis and D. M. Mulvihill, University College Cork, Ireland 13.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.2 The milk protein system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.3 Production of milk protein products . . . . . . . . . . . . . . . . . . . . . . . . . 13.4 Functional properties of milk protein products . . . . . . . . . . . . . . . 13.5 Biological activity of milk protein products . . . . . . . . . . . . . . . . . . 13.6 Food uses of milk protein products . . . . . . . . . . . . . . . . . . . . . . . . . . 13.7 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8 Sources of further information and advice . . . . . . . . . . . . . . . . . . . 13.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Egg proteins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . M. Anton, INRA Nantes UniteÂ 1268 BiopolymeÁres Interactions Assemblages, France and F. Nau and V. Lechevalier, UMR INRA Science et Technologie du Lait et de l'Oeuf, France 14.1 Introduction: technofunctional uses of egg constituents . . . . . . 14.2 Physico-chemistry and structure of egg constituents . . . . . . . . .

252 254 255 256 260 265 270 273 274 274 275 277 277 281 282 296 297 298 298 299 303 317 324 329 341 342 343 359

359 360

Contents 14.3 14.4 14.5 14.6 14.7

ix

Egg yolk emulsions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Egg white foams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Gels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

365 369 373 376 376

15 Vegetable protein isolates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . S. GonzaÂlez-PeÂrez and J. B. Arellano, IRNASA-CSIC, Spain 15.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.2 Chemical composition of vegetable proteins . . . . . . . . . . . . . . . . . 15.3 Protein composition and structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.5 Technical data: functional properties . . . . . . . . . . . . . . . . . . . . . . . . . 15.6 Functional properties for industrial applications . . . . . . . . . . . . . . 15.7 Chemical and enzymatic modification of protein products . . . 15.8 Vegetable proteins: choosing the best functionality for food application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.9 Applications of vegetable proteins in food products . . . . . . . . . 15.10 Nutritional and health effects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.11 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12 References and sources of further reading . . . . . . . . . . . . . . . . . . .

383

16 Protein±polysaccharide complexes and coacervates . . . . . . . . . . . . . C. Schmitt, NestleÂ Research Center, Switzerland and L. Aberkane and C. Sanchez, INPL-ENSAIA, France 16.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.2 Thermodynamic background, theoretical models and energetics of the formation of protein±polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3 Parameters influencing the formation of protein± polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . 16.4 Structure, morphology and coarsening of protein± polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . 16.5 Functional properties of protein±polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.6 Food applications of protein±polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.7 Non-food applications of protein±polysaccharide complexes and coacervates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.8 Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.9 Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.10 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

383 387 389 394 399 401 404 406 406 412 415 418 420 420 422 425 440 445 452 458 460 462 462

x

Contents

17 Gum ghatti . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . S. Al-Assaf, G. O. Phillips and V. Amar, Glyndwr University, UK 17.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.5 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.7 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18

Other exudates: tragancanth, karaya, mesquite gum and larchwood arabinogalactans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Y. LoÂpez-Franco and I. Higuera-Ciapara, Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo, Mexico, F. M. Goycoolea, Universidad de Santiago de Compostela, Spain and Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo, Mexico and W. Wang, Andi-Johnson Konjac Co. Ltd., China 18.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.5 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.7 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

19 Xyloglucan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . K. Nishinari and M. Takemasa, Osaka City University, Japan and K. Yamatoya and M. Shirakawa, Dainippon-Sumitomo Pharma Co. Ltd, Japan 19.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19.2 Origin, distribution and preparation . . . . . . . . . . . . . . . . . . . . . . . . . . 19.3 Structure and fundamental properties . . . . . . . . . . . . . . . . . . . . . . . . 19.4 Interactions with tamarind seed xyloglucan . . . . . . . . . . . . . . . . . . 19.5 Applications in the food industry . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19.6 Regulatory status in the food industry . . . . . . . . . . . . . . . . . . . . . . . 19.7 Physiological effects of xyloglucan . . . . . . . . . . . . . . . . . . . . . . . . . . 19.8 Other aspects and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19.9 References and further reading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Curdlan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . K. Nishinari, Osaka City University, Japan, and Glyndwr University, UK, and Shanghai Jiao Tong University, China, H. Zhang, Shanghai Jiao Tong University, China and T. Funami, San-Ei Gen F.F.I. Inc, Japan 20.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

477 477 480 480 483 487 491 493 495

495 496 501 508 519 525 527 535

535 535 538 546 553 557 558 561 563 567

567

Contents 20.2 20.3 20.4 20.5 20.6 20.7 20.8

Production . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chemical structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Native curdlan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

21

Other microbial polysaccharides: pullulan, scleroglucan, elsinan, levan, alternan, dextran . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . J. K. Park, Kyungpook National University, Korea and T. Khan, COMSATS Institute of Information Technology, Pakistan 21.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.2 Pullulan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.3 Scleroglucan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.4 Elsinan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.5 Levan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.6 Alternan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.7 Dextran . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.8 References and sources of further reading . . . . . . . . . . . . . . . . . . .

22 Cereal -glucans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D. G. Stevenson, National Starch, USA and G. E. Inglett, USDA, USA 22.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.2 Botanical distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.3 Structure and analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.4 Biosynthesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.5 Extraction and purification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.6 Health benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.7 Commercial products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.8 Food applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.9 Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.10 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.11 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.12 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Arabinoxylans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . M. S. Izydorczyk, Canadian Grain Commission, Canada 23.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23.2 Occurrence and content of arabinoxylans . . . . . . . . . . . . . . . . . . . . 23.3 Extraction, isolation and purification of arabinoxylans . . . . . . . 23.4 Molecular structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23.5 Analysis and detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23.6 Physico-chemical properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

xi 568 568 568 570 585 588 588 592 592 593 596 600 603 606 609 612 615 615 617 617 621 622 624 628 632 635 637 638 639 653 653 655 658 664 669 671

xii

Contents 23.7 23.8 23.9

Technological functionality and potential applications of arabinoxylans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Physiological effects of arabinoxylans . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

24 Soluble soybean polysaccharide . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . H. Maeda, Soy Protein Processed Foods Company, Japan and A. Nakamura, Fuji Oil Co., Ltd., Japan 24.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24.4 Basic material properties and characteristics . . . . . . . . . . . . . . . . . 24.5 Functional properties and reported use of soluble soybean polysaccharide in foods and pharmaceutical applications . . . . 24.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24.7 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Cellulosics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . J. C. F. Murray, UK 25.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25.4 Properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25.5 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Bacterial cellulose . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . J. K. Park, Kyungpook National University, Korea, J. Y. Jung, Korea Institute of Patent Information (KIPI), Korea and T. Khan, COMSATS Institute of Information Technology, Pakistan 26.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.2 Historical overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.3 Biosynthesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.4 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.5 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.6 Functional properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.7 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.8 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26.9 References and further reading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Microcrystalline cellulose . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . G. Krawczyk, A. Venables and D. Tuason, FMC BioPolymer, USA 27.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27.2 Raw materials and manufacturing process . . . . . . . . . . . . . . . . . . .

677 681 683 693 693 694 694 696 700 706 706 710 710 711 711 712 714 722 724

725 725 726 728 729 730 733 736 736 740 740 741

Contents 27.3 27.4 27.5 27.6 27.7

xiii

Nutritional and regulatory information . . . . . . . . . . . . . . . . . . . . . . . Physical properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Food applications and functionality . . . . . . . . . . . . . . . . . . . . . . . . . . Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

743 744 745 757 758

28 Hydrocolloids for coatings and adhesives . . . . . . . . . . . . . . . . . . . . . . . A. Nussinovitch, The Hebrew University of Jerusalem, Israel 28.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.2 Today's edible protective films . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.3 Novel products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.4 Inclusion of food additives in edible films . . . . . . . . . . . . . . . . . . . 28.5 Parameters to be considered before, during and after food coating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.6 Hydrocolloid non-food coatings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.7 Film-application techniques and stages . . . . . . . . . . . . . . . . . . . . . . 28.8 Methods for testing coatings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.9 Market estimates for edible films . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.10 The next generation of edible films and possible research directions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.11 Non-food uses and applications of adhesives . . . . . . . . . . . . . . . . 28.12 Adhesive hydrocolloid preparations: pastes and hydrogels . . . 28.13 Adhesion mechanisms of hydrogels . . . . . . . . . . . . . . . . . . . . . . . . . . 28.14 Food uses and applications of adhesives . . . . . . . . . . . . . . . . . . . . . 28.15 Uses and applications of bioadhesives . . . . . . . . . . . . . . . . . . . . . . . 28.16 Structure-function and hydrogel-adherend relationships . . . . . . 28.17 Hydrocolloid adhesion tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.18 Hydrocolloids as wet glues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.19 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28.20 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

760

29 Alginates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . K. I. Draget, Norwegian University of Science and Technology, Norway 29.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.3 Structure and physical properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.5 Gels and gelling technologies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.6 Foods, nutrition and health . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.7 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.8 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29.9 References and sources of further reading . . . . . . . . . . . . . . . . . . .

760 761 769 771 775 776 777 778 779 779 781 782 783 784 785 786 788 790 792 793 807 807 808 809 813 817 823 824 824 825

xiv

Contents

30 Inulin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D. Meyer, Sensus, The Netherlands and J.-P. Blaauwhoed, Cosun Food Technology Centre, The Netherlands 30.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.2 Production process of inulin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.3 Technical properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.4 Nutritional and health benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.5 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.7 Future trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.8 Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 Chitin and chitosan hydrogels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . R. A. A. Muzzarelli, Muzzarelli Consulting, Italy and University of Ancona, Italy and C. Muzzarelli, University of Ancona, Italy 31.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.2 Chitosan chemistry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.3 Properties of chitosans and derivatives . . . . . . . . . . . . . . . . . . . . . . . 31.4 Chitin as a food component . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.5 Nutritional and health effects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.6 Food industry applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.7 Applications in drug delivery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.8 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

829 829 831 831 838 839 843 845 845 845 849 850 851 853 860 861 867 869 876 876

32 Konjac mannan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . S. Takigami, Gunma University, Japan 32.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.2 Manufacture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.3 Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.4 Technical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.5 Uses and applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.6 Regulatory status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32.7 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

889 889 892 894 896 899 900 901

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

902

1 Introduction to food hydrocolloids P. A. Williams and G. O. Phillips, Glyndwr University, UK

Abstract: This introductory chapter provides an overview of the source, market, functional characteristics and regulatory aspects of hydrocolloids used in foods. Examples of a number of different food products are given and the role of the hydrocolloids in controlling their texture and properties is discussed. A brief introduction to the rheological properties of the various types of hydrocolloids is provided and comparisons of the viscosity and viscoelastic behaviour are given. Many hydrocolloids are able to form gels in response to changes in temperature and/or in the presence of ions. The various mechanisms by which gelation occurs are summarised. The interactions that occur in systems containing mixtures of hydrocolloids are considered and combinations demonstrating synergistic behaviour are highlighted. The role of hydrocolloids as dietary fibre is an area of increasing importance because of the associated benefits for health and this area is briefly reviewed. Key words: source of hydrocolloids, hydrocolloids, market, regulatory aspects, rheological properties, viscosity, storage and loss moduli, food products, dietary fibre, health benefits.

1.1

Introduction

The term `hydrocolloids' is commonly used to describe a range of polysaccharides and proteins that are nowadays widely used in a variety of industrial sectors to perform a number of functions including thickening and gelling aqueous solutions, stabilising foams, emulsions and dispersions, inhibiting ice and sugar crystal formation and the controlled release of flavours, etc. The commercially important hydrocolloids and their origins are given in Table 1.1.

2

Handbook of hydrocolloids

Table 1.1 Botanical

Source of commercially important hydrocolloids

trees

cellulose tree gum exudates gum arabic, gum karaya, gum ghatti, gum tragacanth plants starch, pectin, cellulose seeds guar gum, locust bean gum, tara gum, tamarind gum tubers konjac mannan Algal

Microbial Animal

red seaweeds agar, carrageenan brown seaweeds alginate xanthan gum, curdlan, dextran, gellan gum, cellulose Gelatin, caseinate, whey protein, soy protein, egg white protein, chitosan

The food industry, in particular, has seen a large increase in the use of these materials in recent years. Even though they are often present only at concentrations of less than 1% they can have a significant influence on the textural and organoleptic properties of food products. Some typical examples of foods containing hydrocolloids are shown in Fig. 1.1, clearly demonstrating the widespread application of these materials. The specific hydrocolloids used in the production of the individual products shown are: · · · · · · · · · ·

baked beans contain modified corn starch as a thickener hoi-sin sauce contains modified corn starch as a thickener sweet and sour sauce contains guar gum as a thickener Sunny Delight fruit drink contains modified starch as an emulsifier with carboxymethyl cellulose (CMC) and xanthan gum as thickeners the Italian dressing includes xanthan gum as a thickener `light' mayonnaise contains guar gum and xanthan gum as fat replacers to enhance viscosity the yoghurt incorporates gelatin as a thickener rather than a gelling agent the mousse contains modified maize starch as a thickener with guar gum, carrageenan and pectin present as `stabilisers' the Bramley apple pies contain modified maize starch with sodium alginate as gelling agent the fruit pie bars contain gellan gum and the blackcurrant preserve and redcurrant jelly contain pectin as gelling agents

Introduction to food hydrocolloids

3

Fig. 1.1 Examples of food products containing hydrocolloids.

· the trifle contains xanthan gum, sodium alginate and locust bean gum as `stabilisers', modified maize starch as a thickener and pectin as a gelling agent. The changes in modern lifestyle, the ever growing awareness of the link between diet and health and new processing technologies have led to a rapid rise in the consumption of ready-made meals, functional foods and the development of high fibre and low-fat food products. In particular, numerous hydrocolloid products have been developed specifically for use as fat replacers in food. This has consequently led to an increased demand for hydrocolloids. The world

4


hydrocolloids market is valued at around $4.4 billion p.a. with a total volume of about 260,000 tonnes. The market has been growing at the rate of 2±3% in recent years. Hydrocolloid selection is dictated by the functional characteristics required but is inevitably influenced by price and security of supply. It is for these reasons that starches (costing typically < US$1/kg) are the most commonly used thickening agents. It is interesting to note here, however, that xanthan gum (~US$12/kg) is becoming the thickener of choice in many applications. This is because xanthan gum has unique rheological behaviour and its increased use has led to strong competition between supplier companies ensuring that the price has remained at reduced levels. Xanthan gum forms highly viscous, highly shear thinning solutions at very low concentrations and the viscosity is not influenced to any great extent by changes in pH, the presence of salts and temperature. The high viscosity at low shear enables the gum to prevent particle sedimentation and droplet creaming and the shear thinning characteristics ensure that the product readily flows from the bottle after shaking. This explains its widespread application in sauces and salad dressings. Gelatin is by far the most widely used gelling agent, although with the increasing demand for non-animal products and in particular the Bovine Spongiform Encephalopathy (BSE) outbreak in the UK, prices have increased significantly over recent years. There is currently considerable interest in alternative sources of gelatine, notably fish skins, and in the development of gelatin replacements. The carrageenan market has also been very competitive over recent years due to the introduction of cheaper lower refined grades (Processed Euchema Seaweed, PES), which can be used effectively where gel clarity is not important. The price differential between carrageenan and PES has decreased and the use of carrageenans has increased markedly since its use in meat and poultry products was recently approved. A further development has been the introduction of kappa/iota carrageenan hybrids which have potential to provide novel functionality. The gum arabic market has traditionally been erratic due to price fluctuations and security of supply and much effort has been directed at finding alternatives. A number of starch-based substitutes (for example, succinylated starch) were introduced some years ago as alternatives in the emulsification of flavour oils and recent work has been concerned with using pectin (notably sugar beet pectin) as a gum arabic replacement. It has been shown that the emulsification properties of gum arabic and pectin are due to the small amount of protein (2±3%) which is present as in integral part of their structure. This has led to significant interest in the development of polysaccharide±protein complexes (gum arabic lookalikes) which can be formed by a mild heat treatment through the Maillard reaction and by electrostatic interaction. Gellan gum was approved for food use in Japan in 1988 but much later in the USA and Europe, and is beginning to establish its own niche markets. An overview of the hydrocolloids market is given in Figs 1.2(a) and 1.2(b).


5

Fig. 1.2 (a) Value of world market for individual hydrocolloids; (b) Volume of world market for individual hydrocolloids.

1.2

Regulatory aspects

Food hydrocolloids do not exist as a regulatory category in their own right, rather they are regulated either as a food additive or as a food ingredient. With the exception of gelatin, however, the vast majority of food hydrocolloids are currently regulated as food additives. 1.2.1 International The most widely accepted fully international system to regulate the safety of food additives is that set up by a Joint FAO/WHO Conference on Food Additives in September 1955, which recommended that the two organisations collect and disseminate information on food additives. Since that time more than 600 substances have been evaluated and provided with specifications for purity and identity by the Joint/WHO Expert Committee on Food Additives (JECFA). JECFA was first established in the mid-1950s by the FAO and WHO to assess chemical additives in food on an international basis. In the early 1960s the Codex Alimentarius Commission (CAC), an international inter-governmental body, was set up with the primary aims of protecting the health of the consumer and facilitating international trade in food commodities. When CAC was formed, it was decided that JECFA would provide expert advice to Codex on matters relating to food additives. A system was established whereby the Codex Committee on Food Additives and Contaminants (CCFAC), a general subcommittee, identified food additives that should receive priority attention, which were then referred to JECFA for assessment before being considered for inclusion in Codex Food Standards. Specialists invited to serve as members of JECFA are independent scientists who serve in their individual capacities as experts and not as representatives of their governments or employers. The objective is to establish safe levels of intake and to develop specifications for identity and purity of food additives. The reports of the JECFA meetings are published in the WHO Technical Report Series. The toxicological evaluations, which summarise the data that serve as the basis for safety assignments, are

6


published in the WHO Food Additive Series. The specifications are published in the FAO Food and Nutrition Paper Series. The procedure, therefore, is for JECFA to consider the specification of any given additive and to recommend to the Codex Committee for Food Additives and Contaminants (CCFAC) that this be adopted. If they agree after further consideration by all Member States at a Plenary Session, the specification can be confirmed by the full Codex Commission. The ultimate for a food additive, therefore, is to be included into the Codex General Standard for Food Additives. The procedure can prove lengthy, controversial and expensive, since all interested parties can input objections or amendments. However, once accepted, the food additive has world-wide currency. The detailed procedures are described in Codex Alimentarius (General Requirements) Second Edition (Revised 1995). Thus Codex Alimentarius is a collection of internationally adopted food standards presented in a uniform manner. The food standards aim at protecting consumers' health and ensuring fair practice in the food trade. Once accepted, an international number is allocated to the additive which is an acknowledgement of its acceptability. It must be stressed that there are food additives which stay at the JECFA specification level and that this advisory specification is the authority for its use, at the conditions given, until the full acceptance by Codex is given. Gum arabic is one such example, a food hydrocolloid which has been used for more than 2000 years but only finally gained full Codex specification in June 1999. 1.2.2 The European system Clearance of food hydrocolloids by the European Commission was first introduced in 1995 under Directive 95/2/EU for Food Additives other than colours and sweeteners. This is known as the Miscellaneous Additives Directive (MAD), which provides authorisation for a large number of additives from the hydrocolloid group. The majority of these are authorised for general use in foods to Quantum Satis (QS) levels given in Annex 1 of the Directive. Starches, the vast majority of gums, alginates and celluloses enjoy this wide authorisation. Almost immediately following adoption of the original Directive, the Commission began working on proposed amendments, largely to take account of market developments that had not been taken into account in the last stages of the lengthy and complicated legislative process. The historical development of the process must be referred to in order to understand the almost unintelligible machinery adopted by the European Commission in its work. The ground rules for food additives harmonisation were set out in the form of a framework Directive, 89/107/EEC adopted in 1988 (and amended by the European Parliament and Council Directive 94/34/EC). It instructs the Council to adopt in subsequent follow-up Directives · a list of additives to be authorised · a list of foods to which the additives may be added and the levels of use,


7

which gives delegated powers to the Commission to adopt · specifications for each additive · where necessary, methods of analysis and procedures for sampling. A number of general criteria for the use of additives in food are also set out. According to the criteria, food additives may be authorised only if · a reasonable technological need can be demonstrated · they present no hazard to health at the levels proposed · they do not mislead the consumer. Evidence of the need for an additive which, incidentally, plays no part in approvals in the USA, must be provided by the user of the additive, that is the food manufacturer, not the supplier or manufacturer of the additive. The criteria also stipulate that all food additives must be kept under `continuous observation and re-evaluated whenever necessary in the light of changing conditions of use and new scientific observation'. The EC process acknowledges the JECFA system and in the most unintelligible legal language adopted by the Commission adds the following: · Whereas Directive 78/663/EEC should be repealed accordingly: · Whereas it is necessary to take into account the specification and analytical techniques for food additives as set out in the Codex Alimentarius as drafted by JECFA: · Whereas food additives, if prepared by production methods or starting materials significantly different from those included in the evaluation of the Scientific Committee for Food, or if different from those mentioned in this Directive, should be submitted for evaluation by the Scientific Committee for Food for the purposes of a full evaluation with emphasis on the purity criteria. It is surprising that any progress was made at all with all the accompanying bureaucracy. After a most highly political first amendment to the MAD intended to clear Processed Eucheuma Seaweed (E407a) (see Directive 96/85/EC of 19 December 1996), a second amendment was introduced which affected many hydrocolloids. Member States were required to implement the provisions of this Directive in the year 2000. Thus at this time the new authorisation introduced by the current Directive 98/72/EC came into force in all EU Member States. This Directive provides for E401 Sodium alginate, E402 Potassium alginate and E407 Carrageenan, E440 Pectin, E425 Konjac and E412 Guar. Each has controlling conditions associated with the approval. 1.2.3 Other trade blocks While the Codex Alimentarius Commission is the ultimate specification and can provide for approval throughout the world, each country (outside the EU) is free to adopt its own standards. In the USA, for example, the United States Food

8


Chemicals Codex (FCC) also has currency. The FCC is an activity of the Food and Nutrition Board of the Institute of Medicine that is sponsored by the United States Food and Drug Administration (FDA). The current specification of hydrocolloids are to be found in the Fourth Edition (1996). Japan too has its own specifications which include many of the food additives particular to Japan. 1.2.4 The international numbering system for food additives (INS) INS has been prepared by the Codex Committee on Food Additives in order to be able to identify food additives in ingredient lists as an alternative to the declaration of the specific name. The INS is intended as an identification system for food additives approved for use in one or more member countries. It does not imply toxicological approval by Codex. There is an equivalence with the EU system of E numbers, albeit that the EU system is more restricted. Where both INS and E numbers are available they are interchangeable. The list of INS numbers is given in Tables 1.2 and 1.3.

1.3

Thickening characteristics

Hydrocolloids are widely used to thicken food systems and a much clearer understanding of their rheological behaviour has been gained over the last thirty years or so, particularly through the development of controlled stress and controlled strain rheometers capable of measuring to very low shear rates ( 100 nm). Xanthan gum has a unique rheological profile with a very high viscosity at low shear rates (providing good suspending properties) but exhibiting extensive shear thinning characteristics

Fig. 1.6

Viscosity±shear rate profiles for 1% xanthan gum, 1% CMC, 1% guar gum, 20% dextran and 30% gum arabic.


Fig. 1.7

13

Disaccharide repeat units showing 1,4 (top) and 1,6 (bottom) glycodisic linkages. , ' and ! represent the bonds of rotation.

(readily flows on shearing). This behaviour is probably due to weak associations formed between the molecular chains. CMC consists of linear chains of 1,4linked glucose residues while guar gum consists of linear chains of 1,4-linked mannose residues with approximately half having a galactose residue attached through 1,6-linkages. Both adopt relatively stiff ribbon-like conformations (q ~ 10±30 nm). They have typical viscosity±shear rate profiles exhibiting a high viscosity Newtonian plateau at low shear and shear thin above a critical shear rate. Dextran consists of linear chains of 1,6-linked glucose residues with some branching (linked 1,3 and 1,4). It has a very flexible compact structure since the (1,6) glycosidic linkage has three bonds of rotation between the glucose residues rather than two as is the case for other glycosidic bonds (Fig. 1.7). Significant interpenetration of molecular chains does not occur even at concentrations of 20% and hence the viscosity±shear rate profile exhibits Newtonian characteristics. Similar behaviour also occurs for gum arabic which has a very highly branched structure. It should be noted, however, that although the viscosity of dextran and gum arabic is much less than the viscosity of the 1% xanthan, CMC and guar solutions at low shear, they are greater at high shear rates. Charged polymers have a higher viscosity than non-ionic polymers of similar molecular mass because their molecular coils are expanded as a consequence of intramolecular charge repulsions. Addition of electrolyte or adjustment of the pH to reduce the degree of dissociation of the charged groups normally leads to compaction of the coils and a significant drop in viscosity. The main hydrocolloid thickeners used in food products are listed in Table 1.4.

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Table 1.4

Main hydrocolloid thickeners

Xanthan gum Very high low-shear viscosity (yield stress), highly shear thinning, maintains viscosity in the presence of electrolyte, over a broad pH range and at high temperatures. Carboxymethyl cellulose High viscosity but reduced by the addition of electrolyte and at low pH. Methyl cellulose and hydroxypropyl methyl cellulose Viscosity increases with temperature (gelation may occur) not influenced by the addition of electrolytes or pH. Galactomannans (guar and locust bean gum) Very high low-shear viscosity and strongly shear thinning. Not influenced by the presence of electrolyte but can degrade and lose viscosity at high and low pH and when subjected to high temperatures.

1.4

Viscoelasticity and gelation

Hydrocolloid solutions are viscoelastic and can be characterised by the magnitude and frequency dependence of the storage and loss modulii, G0 and G00 respectively. In dilute solutions below C where intermolecular entanglement does not occur, most polymers show G00 greater than G0 over much of the frequency range. Both G0 and G00 show significant frequency dependence, G0 is proportional to the frequency, !, while G0 is proportional to !2 , hence at higher frequencies G0 > G00 . At higher concentrations, in the entanglement region above C , G0 and G00 are still frequency dependent but G0 is greater than G00 over a broader range of frequencies.

Fig. 1.8

G0 and G00 of 0.5% and 2.0% guar gum solutions as a function of frequency.


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This is illustrated in Fig. 1.8 which shows the frequency dependence for guar gum solutions at concentrations of 0.5% and 2.0%. Some polysaccharides, notably xanthan gum, have a tendency to undergo weak intermolecular chain association in solution leading to the formation of a three-dimensional network structure. The junction zones formed can be readily disrupted even at very low shear rates and the network structure is destroyed. In these systems G0 > G00 over a broad frequency range and both have a reduced frequency dependence. This is illustrated in Fig. 1.9(a) which shows the

Fig. 1.9 (a) G0 and G00 of 1% xanthan gum solution as a function of frequency; (b) G0 and G00 of 1.5% amylose gels as a function of frequency.

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mechanical spectrum for a 1% solution of xanthan gum and is typical for `weak gels'. Other polysaccharides, for example amylose, agarose, carrageenan and gellan gum, can form stable intermolecular regions of association (referred to as junction zones) and as a consequence strong gel structures are produced. For these systems G0 G00 and both are virtually independent of frequency over this frequency range (Fig. 1.9(b)). Hydrocolloid gels are referred to as `physical gels' because the junction zones are formed through physical interaction, for example, by hydrogen bonding, hydrophobic association, cation-mediated crosslinking, etc., and differ from synthetic polymer gels which normally consist of covalently crosslinked polymer chains. Some hydrocolloids form thermoreversible gels and examples exist where gelation occurs on cooling or heating. Some form non-thermoreversible gels. In such cases gelation may be induced by crosslinking polymer chains with divalent cations. Gels may be optically clear or turbid and a range of textures can be obtained. Gel formation occurs above a critical minimum concentration which is specific for each hydrocolloid. Agarose, for example, will form gels at concentrations as low as 0.2%, while for acid-thinned starch, a concentration of ~15% is required. Gel strength increases with increasing concentration. Molecular mass is also important. It has been shown that gel strength increases significantly as molecular mass increases up to ~100,000 but then becomes independent of molecular mass at higher values. The principal hydrocolloid gelling agents are listed in Table 1.5 and a comparison of their relative gel textures is illustrated in Fig. 1.10. An increase in brittleness is usually accom-

Fig. 1.10

Qualitative comparison of the textures of gels produced by different hydrocolloids.

Introduction to food hydrocolloids Table 1.5

17

Main hydrocolloid gelling agents

1. Thermoreversible gelling agents Gelatin Gel formed on cooling. Molecules undergo a coil-helix transition followed by aggregation of helices. Agar Gel formed on cooling. Molecules undergo a coil-helix transition followed by aggregation of helices. Kappa Carrageenan Gel formed on cooling in the presence of salts notably potassium salts. Molecules undergo a coil-helix transition followed by aggregation of helices. Potassium ions bind specifically to the helices. Salts present reduce electrostatic repulsion between chains promoting aggregation. Iota Carrageenan Gel formed on cooling in the presence of salts. Molecules undergo a coil-helix transition followed by aggregation of helices. Salts present reduce electrostatic repulsion between chains promoting aggregation. Low methoxyl (LM) pectin Gels formed in the presence of divalent cations, notably calcium at low pH (3±4.5). Molecules crosslinked by the cations. The low pH reduces intermolecular electrostatic repulsions. Gellan gum Gels formed on cooling in the presence of salts. Molecules undergo a coil-helix transition followed by aggregation of helices. Salts reduce electrostatic repulsions between chains and promote aggregation. Multivalent ions can act by crosslinking chains. Low acyl gellan gels are thermoreversible at low salt concentrations but non-thermoreversible at higher salt contents (> 100mM) particularly in the presence of divalent cations. Methyl cellulose and hydroxypropylmethyl cellulose Gels formed on heating. Molecules associate on heating due to hydrophobic interaction of methyl groups. Xanthan gum and locust bean gum or konjac mannan Gels formed on cooling mixtures. Xanthan and polymannan chains associate following the xanthan coil-helix transition. For locust bean gum the galactose deficient regions are involved in the association. 2. Thermally irreversible gelling agents Alginate Gels formed on the addition of polyvalent cations notably calcium or at low pH (< 4). Molecules crosslinked by the polyvalent ions. Guluronic acid residues give a buckled conformation providing an effective binding site for the cations (egg box model). High methoxyl (HM) pectin Gels formed at high soluble solids (e.g. 50% sugar) content at low pH < 3.5. The high sugar content and low pH reduce electrostatic repulsions between chains. Chain association also encouraged by reduced water activity. Konjac mannan Gels formed on addition of alkali. Alkali removes acetyl groups along the polymer chain and chain association occurs. Locust bean gum Gels formed after freezing. Galactose deficient regions associate.

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panied by an increase in the tendency to undergo syneresis and is attributed to an increase in the degree of aggregation of molecular chains.

1.5

Synergistic combinations

Mixtures of hydrocolloids are commonly used to impart novel and improved rheological characteristics to food products and an added incentive is a reduction in costs. Classic examples include the addition of locust bean gum to kappa carrageenan to yield softer more transparent gels and also the addition of locust bean gum to xanthan gum to induce gel formation. The nature of the synergy can be due to association of the different hydrocolloid molecules or to phase separation. The various effects that can occur are summarised schematically in Fig. 1.11. If the two hydrocolloids associate then precipitation or gelation can occur. Oppositely charged hydrocolloids (e.g. a protein below its isoelectric point and an anionic polysaccharide) will associate and may form soluble or insoluble complexes depending on the pH, mixing ratio and ionic strength of the solution. There is evidence to show that some stiff polysaccharide molecules (xanthan gum, carrageenan, etc.) will associate with galactomannans and glucomannans leading to gel formation. If the two hydrocolloids do not associate, as is commonly the case, then at `low' concentrations they will appear to exist as a single homogeneous phase while at higher concentrations they will separate in time into two liquid phases each enriched in one of the hydrocolloids. The phase separation process involves the formation of `water-in-water' emulsions which consist of droplets enriched in one hydrocolloid dispersed in a continuous phase enriched in the other. Whether the hydrocolloid is present in the dispersed or continuous phase depends on the relative concentrations. If either or both of the hydrocolloids can form gels independently, then phase separation and gelation will occur simultaneously. The characteristics of the resultant gel will depend on the relative rates of these two processes. Careful selection of hydrocolloid type and concentration can, therefore, lead to the formation of a broad range of gel textures and this is currently an area receiving considerable attention.

Fig. 1.11 Schematic representation of the interactions that occur in solutions containing mixtures of hydrocolloids.


1.6

19

Hydrocolloid fibres

Because there is a growing belief throughout the world that natural fibre foods are an integral part of a healthy lifestyle, food producers source an increasing proportion of their raw materials from nature itself. There is a growing demand from an increasingly health-conscious consumer for reduced fat and enhanced fibre foods of all types. If this can be achieved using materials which have low calorific value, further health benefits will result. Foods containing such ingredients will need to match the quality of the original product and without adverse dietary effects. This target cannot be achieved without the scientific use of thickeners, stabilisers and emulsifiers, particularly of the `natural type'. This calls for fibres, which can interact with water to form new textures and perform specific functions, which itself requires the use of hydrocolloids. In 1998 the world market for such hydrocolloids of the fibre type was US$2.83 million and is set to grow significantly to meet the health aspirations of the consumer. It is the task of the food scientist to provide the hydrocolloids in the most appropriate form for inclusion in the food product. This requires an understanding of their structure and the way in which they act to produce the desired function in the food. Dietary fibre was first described as the skeletal remains of plant cell walls, which are resistant to hydrolysis, by the digestive enzymes of man. Since this excluded polysaccharide fibres in the diet, the definition was subsequently expanded to include all polysaccharides and lignin, which are not digested by the endogenous secretions of the human digestive tract. Dietary fibre thus mainly comprises non-starch polysaccharides, and indeed has been defined by Englyst and others as the `polysaccharides which are resistant to the endogenous enzymes of man'. Industrialised countries now generally recognise the healthgiving properties of increased consumption of fibre and reduced intakes of total and saturated fat. In this respect `fibre' is used in a non-specific way, but is generally taken to mean structural components of cereals and vegetables. More recently the concept of `soluble fibre' has emerged which assists plasma cholesterol reduction and large-bowel fermentation. The properties of such soluble and insoluble fibre allow them to perform both in a physical role and also to ferment through colonic microflora to give shortchain fatty acids (SCFA), mainly acetate, propionate and butyrate. These have a very beneficial effect on colon health through stimulating blood flow, enhancing electrolyte and fluid absorption, enhancing muscular activity and reducing cholesterol levels. The various hydrocolloids described in this handbook fall into this category. 1.6.1 The physical effect To be effective dietary fibre must be resistant to the enzymes of the human and animal gastrointestinal tract. If physically suitable it can work effectively as a result of its bulking action. In the stomach and small intestine the fibre can increase digested mass, leading to faecal bulking, which readily explains the

20


relief of constipation, which is one of fibre's best documented effects. It can increase stool mass and ease laxation very efficiently. This behaviour has considerable human and agricultural importance. The growth of the ruminant animal depends on the fermentable fibre content of the stockfeed. Soluble as well as non-soluble fibres exert their actions in the upper gut through their physical properties. Those which form gels or viscous solutions can slow down the transit in the upper gut and delay glucose absorption, best explained in terms of `viscous drag'. Thus the reduction in glycemic response by soluble fibres can be explained. 1.6.2 Fermentation product effects Large bowel micro-organisms attack the soluble fibres, in fermentation resembling that in the rumen of obligate herbivores such as sheep and cattle. The products too are similar: short-chain fatty acids (SCFA), gases (hydrogen, carbon dioxide and methane) and an increased bacterial mass. The principal SCFAs are the same in humans as in ruminants, and the concentrations are similar too, particularly for omnivorous animals with a similar digestive physiology (for example, the pig). The increased bacterial cell mass also has a positive effect on laxation. Faeces are approximately 25% water and 75% dry matter. The major components are undigested residuals plus bacteria and bacterial cell wall debris. These form a sponge-like, water-holding matrix which conditions faecal bulk and cell debris. The ability of different fibres to increase faecal bulk depends on a complex relationship between chemical and physical properties of the fibre and the bacterial population of the colon. The production of SCFAs and their beneficial effects in humans and ruminant species has been well established for a considerable time, but the effect was not thought to be relevant to the carnivorous dog and cat. Now this too has been demonstrated. 1.6.3 Health benefits Whether by physical bulking action or through the production of SCFAs, several health advantages are now established. Increasing fibre (20±30 grams per day in humans) can eliminate constipation through increased faecal bulking and waterholding. The fermentation to produce SCFAs can also assist, since propionate stimulates colonic muscular activity and encourages stool expulsion. It was at one time thought that fibre lodged in the colon could lead to inflammation and herniation. This has now been disproved, and fibre can now relieve diverticular disease conditions, probably in the same way as it relieves constipation. Applying a solution of SCFA into the colon of ulcerative colitis patients or into the defunctioned portion of surgical patients has given rise to substantial remission in colitis. It could be that the condition arises due to a defect in the fermentation process in these patients or in the products. SCFAs stimulate water and electrolyte absorption by the mucosa and enhance


21

their transport through improving colonic blood flow. Fibre fermentation also reduces the population of pathogenic bacteria such as Clostridia and can prevent diarrhoea due to bacterial toxins. Epidemiological studies have shown repeatedly that populations with high levels of fibre in their diet have reduced risk of colon cancer. Protection may be through the SCFA butyrate, which inhibits the growth of tumour cells in vitro. When applied to the companion animal, the increased production of SCFAs increases gut acidity marginally, which reduces the activity of putrefaction and pathogenic bacteria and so lowers toxin and thus reduces bad odours and bad smelling faeces. The low level of toxin production reduces the load on the liver and results in better coat and skin quality. Therefore, the ageing animal can look better and produce less offensive faeces. The behaviour of SCFAs in the intestine can influence the immune system. Thus protection is possible against colonisation by opportunistic bacteria, and the improved colonisation of beneficial indigenous bacteria in the gut gives greater resistance to infectious bacteria.

1.7

Future trends

The introduction of totally new hydrocolloids for food use is restricted by the large financial investment required to obtain the necessary legislative approval. Probably the last hydrocolloid to go through this process was gellan gum. There are certain hydrocolloids, however, that have a long history of use in food in other parts of the world that have potential for use as food additives in the USA and Europe. A typical example is konjac mannan which has been used for hundreds of years in Japan to produce noodles and is eaten as a food in own right. This material has only recently gained approval for use as an additive in the West. When dissolved in water konjac mannan has similar properties to locust bean gum but produces higher viscosity solutions and also has a stronger synergistic interaction with kappa carrageenan and xanthan gum. The search for new synergistic combinations continues and this is becoming more fruitful as our understanding of the interactions and phase behaviour of hydrocolloid mixtures increases at the molecular level. New processing procedures are also being introduced and an area of particular interest at present is the formation of sheared gels to give novel rheological characteristics. This involves applying shear as the hydrocolloid is undergoing gelation and usually results in the formation of micron-size hydrocolloid gel particles. At a sufficiently high concentration, the systems formed can have a very high low-shear viscosity and display strong shear thinning characteristics. As discussed above, although hydrocolloids have historically been used in foods to control the rheological properties and texture, consumers are being made increasing aware of their nutritional benefits. Many hydrocolloids (e.g., locust bean gum, guar gum, konjac mannan, gum arabic, xanthan gum and pectin) for instance, have been shown to reduce blood cholesterol levels. Others

22


(e.g., inulin and gum arabic) have been shown to have prebiotic effects. They are resistant to our digestive enzymes and pass through the stomach and small intestine without being metabolised. They are fermented in the large intestine to yield short chain fatty acids and stimulate the specific growth of beneficial intestinal bacteria, notably, bifidobacteria, and reduce the growth of harmful micro-organisms such as clostridia. All in all the hydrocolloid market is currently very buoyant and the prospects for future growth are excellent.

1.8

Bibliography

and VAN VLIET, T. (2003) Food Colloids: Biopolymers and Materials. Royal Society of Chemistry, Cambridge. DOXASTAKIS, G. and KIOSSEOGLOU, V. (2000) Novel Macromolecules in Food Systems. Elsevier Science BV, Amsterdam. DUMITRIU, S. (2005) Polysaccharides: Structural Diversity and Functional Versatility, 2nd edition. Marcel Dekker, New York. MCKENNA, B.M. (2003) Texture in Food. Woodhead Publishing Ltd, Cambridge. STEPHEN, A.M., PHILLIPS, G.O. and WILLIAMS, P.A. (2006) Food Polysaccharides and their Application. CRC Taylor and Francis, Boca Raton, FL. SUNGSOO CHO, S. and DREHER, M.L. (2001) Handbook of Dietary Fibre. Marcel Dekker, New York. WILLIAMS, P.A. and PHILLIPS, G.O. (2000) Gums and Stabilisers for the Food Industry 10. Royal Society of Chemistry, Cambridge. WILLIAMS, P.A. and PHILLIPS, G.O. (2002) Gums and Stabilisers for the Food Industry 11. Royal Society of Chemistry, Cambridge. WILLIAMS, P.A. and PHILLIPS, G.O. (2004) Gums and Stabilisers for the Food Industry 12. Royal Society of Chemistry, Cambridge. WILLIAMS, P.A. and PHILLIPS, G.O. (2006) Gums and Stabilisers for the Food Industry 13. Royal Society of Chemistry, Cambridge. WILLIAMS, P.A. and PHILLIPS, G.O. (2008) Gums and Stabilisers for the Food Industry 14. Royal Society of Chemistry, Cambridge. DICKINSON, E.

2 Hydrocolloids and emulsion stability E. Dickinson, University of Leeds, UK

Abstract: This chapter describes the physico-chemical principles underlying the functional role of hydrocolloids in oil-in-water emulsions. Basic terms such as emulsifier and stabilizer are defined, and the origins of electrostatic and steric interaction potentials are explained. The chapter discusses the main factors controlling flocculation, creaming, coalescence and Ostwald ripening, distinguishing between the differing effects of adsorbing and nonadsorbing hydrocolloids. The reader's attention is specifically directed towards new understanding concerning the rheological and microstructural control of emulsion stability by non-adsorbing hydrocolloids, and the great potential of electrostatic protein±polysaccharide interactions at the oil±water interface for enhancing emulsion properties. Key words: emulsion stability, depletion flocculation, rheology and microstructure, hydrocolloid emulsifiers, protein±polysaccharide complexes.

2.1

Introduction

An emulsion is a dispersion of one liquid (the dispersed phase) as small spherical droplets in another immiscible liquid (the continuous phase). The two main types of emulsions are oil-in-water (O/W) and water-in-oil (W/O). Food emulsions of the oil-in-water type include, for example, milk, cream, salad dressings, sauces and beverages; examples of the water-in-oil type are butter and margarine. The oil phase is either a flavour oil (in soft drinks) or a triglyceride oil (in dairy emulsions). In the latter case the oil phase is semi-solid at ambient temperatures due to the presence of dispersed fat crystals. Some emulsion products also contain other kinds of dispersed phases ± gas bubbles (in whipped cream), starch granules (in cake batter) and ice crystals (in ice-cream). Despite the wide diversity of structures, compositions and textures of food emulsions,

24


there are some basic underlying principles that can be reliably used to understand and predict their general behaviour. One generally important factor influencing their stability properties is the presence of hydrocolloids. Emulsions are thermodynamically unstable. With time they tend to break down into their constituent oil and aqueous phases. The term èmulsion stability' therefore refers to the ability of an emulsion to resist this breakdown, as indicated by growth in average size of droplets or change in their spatial distribution within the sample. The more slowly that these properties change, the more stable is the emulsion. In practice, stability is a relative term which depends on the context. For some food emulsions, such as cake batters or cooked sauces, the required time-scale for stability is only a few minutes or hours. But for other products, such as soft drinks and cream liqueurs, emulsion stability must be maintained over a period of several months or years. A hydrocolloid ingredient may act as an emulsifying agent, as a stabilizing agent, or in both of these roles. An emulsifying agent (emulsifier) is a surfaceactive ingredient which adsorbs at the newly formed oil±water interface during emulsion preparation, and it protects the newly formed droplets against immediate recoalescence. Given that polysaccharides are predominantly hydrophilic in molecular character, and most hydrocolloids are not surface-active, they cannot act as primary emulsifying agents. There is really only one hydrocolloid ± namely, gum arabic ± which is commonly employed as an emulsifying agent. The main emulsifying agents used in food processing are the proteins, especially those derived from milk or eggs. A stabilizing agent (stabilizer) is an ingredient that confers long-term stability on an emulsion, possibly by a mechanism involving adsorption, but not necessarily so. In O/W emulsions, the stabilizing action of hydrocolloids such as xanthan, carboxymethycellose, carrageenan, etc., is traditionally attributed to the structuring, thickening and gelation of the aqueous continuous phase. In the context of this chapter, the expression èmulsifying agent' is to be preferred over the more concise èmulsifier'. This is because the latter term normally implies membership of the class of small-molecule surfactants, comprising lipid-based ingredients such as monoglycerides (e.g., GMS), phospholipids (lecithin) and polysorbates (Tweens). The functional role of these smallmolecule emulsifiers in food technology is typically not for emulsion making, but for other reasons: controlling fat morphology and crystallization; promoting shelf-life through interaction with starch; and destabilizing emulsions by competitive protein displacement from the oil±water interface (Dickinson, 1992). Figure 2.1 illustrates the four main kinds of instability processes exhibited by O/W emulsions: creaming, flocculation, coalescence and Ostwald ripening. (For W/O emulsions, the processes are the same, except that sedimentation replaces creaming.) Flocculation is probably the most subtle and complicated phenomenon to control, because it can be triggered by so many different factors, and the resulting emulsion properties can be quite different depending upon whether the flocculation is weak or strong. In dairy-type O/W emulsions, at or below ambient temperature, instead of the full coalescence of liquid droplets, we have

Hydrocolloids and emulsion stability

25

Fig. 2.1 Schematic representation of the key mechanisms of O/W emulsion instability: (a) stable dispersion of droplets; (b) creaming; (c) flocculation (weak); (d) flocculation (strong); (e) coalescence; (f) Ostwald ripening.

so-called `partial coalescence' (`clumping') of semi-crystalline globules. In practice, two or more of the phenomena shown in Fig. 2.1 may happen at the same time, and the presence of one mechanism (e.g., flocculation) may trigger or enhance another (e.g., creaming or partial coalescence). Emulsion phase inversion, as in the shear-induced transformation of cream (O/W) into butter (W/O), is a multi-mechanism process. Detailed theoretical analysis of these primary stability mechanisms is beyond the scope of this chapter. Readers looking for such an in-depth treatment are referred to the many standard texts (Dickinson and Stainsby, 1982; Hunter, 1986; Dickinson, 1992; Evans and Wennerstrom, 1994; Hiemenz and Rajagopalan, 1997; Walstra, 2003; Friberg et al., 2004; McClements, 2005a; Leal-Calderon et al., 2007). For any researcher embarking on a new experi-

26


mental investigation of the stability properties of emulsions, the recent critical overview of techniques and methodologies by McClements (2007) is recommended reading.

2.2

Principles of emulsion stability

A stable emulsion is one where the droplets remain sufficiently small and well separated that Brownian motion alone keeps them evenly dispersed throughout the continuous phase. The physico-chemical principles of O/W emulsion stability are based on the classical colloid theories of electrostatic and steric stabilization (Dickinson, 1992; McClements, 2005a). Electrostatic stabilization arises from the presence of electrical charge on the surface of the droplets, or more usually on the adsorbed stabilizer layer at the surface of the droplets. The greater the charge density at the surface, and the lower the ionic strength (electrolyte concentration) of the continuous phase, the more stable is the emulsion. Steric stabilization arises from the presence of a polymeric (steric) barrier at the droplet surface. To confer long-term stabilization, this polymer must be present at sufficient concentration to cover the oil±water interface completely, and it must remain permanently attached to the surface, with at least part of the molecule projecting away from the surface into the aqueous medium. Steric stabilization is increasingly supplemented by electrostatic stabilization in emulsions containing adsorbed proteins at pH values well away from the protein's isoelectric point (pI) (Damodaran, 2005). Whether emulsion droplets will remain dispersed or will tend to stick together depends on the nature of the interparticle pair potential between the droplet surfaces. Generally speaking, colloidal stability requires that the interparticle repulsion should be of sufficient range and strength to overcome the combined effects of gravity, convection, Brownian motion, and the ubiquitous short-range attractive forces, which together drive the system towards its final and inevitable phase-separated equilibrium condition. Figure 2.2 shows two possible forms of the interaction potential (measured in units of the thermal energy, kT) as a function of the surface-to-surface separation (measured in arbitrary units of the order of nanometres). The shape of the potential U(d) at any separation d tells us about the nature and strength of the interaction force between the surfaces. That is, the force F is equal to the (negative) derivative of the potential, i.e., F ÿdUd=dd. Potential A in Fig. 2.2 corresponds to a stable system where the interaction force is repulsive or zero (F 0) at all droplet separations. Potential B corresponds to a more complicated situation in which the interaction force is strongly attractive at close separations (F < 0, d < 5), repulsive at medium separations (F > 0), and weakly attractive or zero at larger separations (F 0, d 12). In this latter case, the system is stable with respect to coagulation (i.e., coalescence of emulsion droplets) but unstable with respect to reversible flocculation. In any particular emulsion, what determines whether the potential U(d) is of type A or type B, or if it has some other


27

Fig. 2.2 Theoretical interaction potential between a pair of spherical emulsion droplets. The energy U(d) (in units of kT) is plotted as a function of surface-to-surface separation d (arbitrary units). Curve A corresponds to a pure repulsive interaction. Curve B corresponds to a DLVO-type potential having a potential energy barrier more than sufficient to confer colloidal stability (pmin = primary minimum, pmax = primary maximum, smin = secondary minimum). See text for further details.

functional form, is the delicate balance between the various types of molecular forces contributing to the overall interaction. 2.2.1 Electrostatic interactions An important contribution to the stabilization of many food O/W emulsions arises from interdroplet electrostatic repulsion. As two identically charged spheres approach, there is an increase in the concentration of small ions of opposite charge (counterions) in the space between the surfaces. The consequent increase in local osmotic pressure in this gap leads to a repulsive force between the surfaces. As this repulsion has its origin in the overlap of the electrical double-layers surrounding the spheres, it is commonly referred to as the (electrical) double-layer repulsion. For a pair of spheres of radius a, the doublelayer potential has the form UR d 2r 0 a

2 0

ln 1 expÿd;

2:1

where r is the dielectric constant of the aqueous medium, 0 is the permittivity of free space, 0 is the surface potential, and ÿ1 is the Debye length (a measure of the thickness of the double-layer). This equation is properly valid for systems with moderate surface potentials (j 0 j 30 mV) which is typically the case for food emulsions. For a simple 1:1 electrolyte (e.g., NaCl), the double-layer thickness is given by ÿ1 =nm 0:30I=mol dmÿ3 ÿ1=2 ;

2:2

28


where I is the salt concentration (ionic strength). With increasing salt concentration, the double-layer becomes thinner, and the electrostatic repulsion becomes weaker. Strong forces of attraction occur between pairs of colloidal particles at close separations. These forces can be considered to arise from a sum of all the van der Waals forces acting between individual molecules in the different particles. For spheres of radius a, the resulting net van der Waals attraction is given by UA d ÿAH a=12d;

2:3

where AH is the Hamaker constant (5 10±21 J for oil droplets in water). For very fine oil droplets, van der Waals attractive forces are important only at very close separations, but for coarse droplets they can be of quite long range (tens of nanometres). In the absence of any opposing repulsive forces (e.g., for uncharged surfaces, or in aqueous media of high ionic strength), dispersed droplets become spontaneously aggregated (coagulated) under the influence of these ubiquitous van der Waals forces. This situation is highly unstable, leading to immediate droplet coalescence. In the classical theory of electrostatic stabilization, the double-layer energy UR (equation 2.1) and the van der Waals energy UA (equation 2.3) are added together algebraically to produce an overall pair potential: Ud UR d UA d:

2:4

Equation 2.4 is commonly referred to as the DLVO potential after the four scientists (Derjaguin, Landau, Verwey and Overbeek) most closely associated with the theory. Due to the different functional forms of equations 2.1 and 2.3, the term UA(d) tends to be more important at smaller and larger values of d, and the term UR(d) is relatively more important at intermediate separations (d 2ÿ1 ). Potential A in Fig. 2.2 corresponds to the case where the double-layer repulsion is entirely predominant. Such a situation would correspond to a fine dispersion of highly charged droplets in an aqueous medium of low ionic strength. Under such conditions, the term UR(d) is sufficient to overcome UA(d) at all separations d, and the emulsion can be considered to be electrostatically stabilized. In estimating UR(d) from DLVO theory, it is common practice in formulae such as equation 2.1 to replace the surface potential 0 (more correctly, the Stern potential ) by the so-called zeta potential (-potential), i.e., the value of the potential at the plane of shear. The -potential is a convenient and popular quantity because it is readily measurable in the laboratory. For most food emulsions, however, this measurement is open to misinterpretation because the classical double-layer model is not properly applicable to polymer-coated surfaces. In particular, the presence of adsorbed polymer tends to shift the plane of shear considerably away from the droplet surface; so we actually have . Nonetheless, the value of can be quite useful as an indicator of the likely importance of electrostatic contributions to emulsion stability, especially when it is small, or its sign changes from ve to ÿve (or vice versa), as may


29

occur following adjustment of pH or introduction of a new species (e.g., hydrocolloid) into the aqueous medium. As a general rule, for an emulsion containing droplets with < 15 mV, one cannot explain stability entirely in terms of double-layer repulsion. This is true even for aqueous media of very low ionic strength, despite such solution conditions being rarely encountered in food formulations. Potential B in Fig. 2.2 corresponds to the situation where the electrostatic repulsion is predominant at intermediate separations. Such a situation would correspond to the case of moderately large charged droplets (a > 1 m) in an aqueous medium of low ionic strength. Curve B is characterized by a primary minimum (pmin) at small separations (d 2 nm), a primary maximum (pmax) at d 6 nm, and a secondary minimum (smin) at d 12 nm. Here the magnitude of the primary maximum (Umax 100 kT) is very much more than sufficient to prevent the droplet pair from aggregating into the primary minimum under the influence of the short-ranged van der Waals forces. As a rough rule of thumb, a barrier height Umax of at least 15±20 kT is required to provide long-term colloidal stability with respect to aggregation in the primary minimum (and associated emulsion droplet coalescence). However, a system described by potential B would still be unstable with respect to flocculation in the secondary minimum. This is especially the case for coarse emulsion droplets (a few micrometres in diameter) since UA increases linearly with the droplet size (see equation 2.3). 2.2.2 Steric interactions When protein or hydrocolloid is present in an adsorbed layer around the emulsion droplets, there is an additional repulsive contribution to the interparticle pair potential due to the specific polymeric character of the stabilizer layer. There are three main requirements for a polymer to be effective as a steric stabilizer: (i) the adsorbed layer should be sufficiently thick; (ii) the coverage of the interface should be complete; and (iii) the polymer should be strongly (irreversibly) attached to the interface. Theory and experiment have demonstrated (Dickinson, 2006) that an adsorbed layer formed from a biopolymer, or a mixture of biopolymers, should be at least several nanometres in thickness to provide effective steric stabilization. This implies that part of the stabilizing macromolecule should be rather hydrophilic, with a tendency to distribute itself preferentially away from the oil±water interface. In other words, the aqueous continuous phase should be a `good solvent' for part of the adsorbed polymer in order for it to be able to act effectively as a steric stabilizer. Reduction of this solvent quality (e.g., by change in temperature or pH, or by adding a cosolvent like ethanol) is detrimental to effective steric stabilization. Steric repulsion arises from the entropically unfavourable overlap and compression of the adsorbed layers when polymer-coated droplets approach close together. The overlap of polymer layers is unfavourable because it leads to a local osmotic pressure gradient associated with the free energy of mixing of

30


solvent and polymer segments in the interdroplet overlap zone. The compression of layers is also unfavourable because it restricts the volume available to each polymer chain, leading to a statistical bias away from the most-probable (equilibrium) distribution of configurations, in an analogy with the elastic deformation of a rubber-like polymer network. The overall distance-dependent free energy change is given by GS d Gm d Gvr d;

2:5

where Gm is the `mixing' (osmotic) free energy arising from polymer layer overlap and Gvr is the `volume restriction' (elastic) free energy arising from polymer layer compression. By analogy with equation 2.4, the overall pair potential is obtained by combining the steric free energy with the van der Waals energy: Ud GS d UA d:

2:6

For sterically stabilized droplets of small size ( 1 m) under good solvent conditions, the steric free energy predominates at all separations, and the form of the overall potential U(d) is qualitatively similar to that of curve A in Fig. 2.2. Assuming that the polymer stabilizer stays irreversibly adsorbed, the highly repulsive term Gvr always dominates the overall interaction at very close separations, even under poor solvent conditions. Hence, in contrast to the electrostatic stabilization case, the sterically stabilized system has no primary minimum. This means that, as long as the oil±water interface is fully covered by the thick polymer layer, the droplets are extremely stable with respect to coalescence. On the other hand, large sterically stabilized droplets can be susceptible to flocculation due to the presence of an energy minimum in U(d) somewhat analogous the DLVO secondary minimum of curve B in Fig 2.2. Invariably, in a food O/W emulsion, the droplets carry a significant electrical charge, and the droplet surfaces are also coated with adsorbed biopolymers. Hence most food emulsions are stabilized by a combination of electrostatic and steric mechanisms. In fact, in the same colloidal system there is intimate coupling of factors affecting both mechanisms. That is, for the most effective stabilizing biopolymers, it is the presence of hydrated charged regions of the macromolecules which confers substantial thickness to the adsorbed layer, as well as significant charge density at the plane of shear. At the same time, the adsorbed biopolymer layer affects the DLVO-type potential in two different ways: (i) by changing the value of the effective Hamaker constant in UA (see equation 2.3), and (ii) by changing the ionization of surface groups and partitioning of mobile ions between bulk phase and interface, causing perturbation of the double-layer repulsion UR. This complexity makes the identification of the main mechanism of stabilization difficult in specific cases. Nevertheless, generally speaking, for a protein-stabilized emulsion at a moderate electrolyte concentration and a pH not too far away from pI, steric stabilization is likely to be the predominant mechanism.


31

2.2.3 Flocculation Flocculation is defined as the coming together of emulsion droplets without rupture of the protective stabilizing layer. It occurs when the overall pair interaction energy at some separation d becomes appreciably negative, i.e., jUdj has a value of the order of kT (weak and reversible flocculation) or is much larger (strong and irreversible flocculation). An emulsion may become flocculated in different ways: · Lowering of the surface charge density. Flocculation may be induced by pH change or specific binding of ions (e.g., Ca2+). This is most likely in a system where electrostatic repulsion makes an overriding contribution to U(d), or where the configurations of the stabilizing polymers are especially sensitive to the charge distribution. · Increasing the ionic strength. The addition of simple salts to the aqueous phase reduces the thickness of the electrical double-layer and so diminishes the range of the electrostatic repulsion. · Lowering of the solvent quality. Flocculation is induced under thermodynamic conditions favouring reduced solubility of the adsorbed stabilizer in the aqueous medium, e.g., arising from pH change or ethanol addition. · Formation of polymer bridges during emulsification. Bridging flocculation (`clustering') arises when insufficient emulsifier is readily available during emulsification to saturate the droplet surfaces. Hence adsorbed polymer molecules or particles (e.g., casein micelles) become shared between neighbouring droplets. · Formation of polymer bridges after emulsification. Bridging may arise from cross-linking of adsorbed protein molecules on different droplets as a result of heat treatment. Bridges may also be formed through the development of associative interactions between a hydrocolloid additive and protein adsorbed at the oil±water interface (see Section 2.4.2). · Influence of non-adsorbed species. The presence of various non-adsorbed species (micelles, nanoparticles or polymers) causes depletion flocculation. The effect can be explained in terms of an extra attractive (entropic) contribution to U(d) arising from the exclusion of these species from the narrow gap between closely approaching droplet surfaces (see Section 2.3.2).

2.2.4 Creaming Creaming is the movement of oil droplets under gravity to form a concentrated cream layer at the top of an O/W emulsion. Stokes' Law tells us that the creaming speed v of an isolated rigid droplet of density and radius a is v 2a2 0 ÿ g=90 ;

2:7

where 0 and 0 are respectively the density and (Newtonian) viscosity of the continuous phase, and g is the acceleration due to gravity. Equation 2.7 is strictly

32


applicable to an emulsion that is dilute, monodisperse and non-flocculated. For such a system, creaming may be slowed down in three main ways: 1. Reduction of droplet size. The mean droplet size is mainly determined by the emulsifier concentration and the efficiency of the emulsification equipment. Using a high-pressure homogenizer with an adequate emulsifier/oil ratio under favourable emulsifying conditions (e.g., with milk protein at neutral pH), it is relatively straightforward to prepare fine emulsions (< 1 m) that are non-flocculated and reasonably monodisperse. Nevertheless, some creaming is inevitable because it is impossible in practice to eliminate completely the small fraction of larger droplets. 2. Reduction of density difference between phases. The density difference between liquid milk fat and water is 1 102 kg mÿ3 at ambient temperatures. Apart from triggering the (partial) crystallization of the fat phase in the oil droplets, which reduces the density difference (and hence the creaming speed) by about 20%, there is little that can be done to influence the density difference in dairy emulsions. In flavour oil emulsions prepared for the soft drinks industry, however, it is common practice to incorporate an oil-soluble `weighting agent' (e.g., ester gum, damar gum) in order to adjust the density of the citrus oil droplets towards that of the aqueous continuous phase (Tan, 2004). 3. Increase in effective viscosity of aqueous medium. Rheological control of the aqueous phase is the main function of hydrocolloids in food formulations. To make meaningful predictions of the effect of hydrocolloids on creaming stability, the viscosity 0 appearing in equation 2.7 should be the apparent viscosity of the solution measured at very low shear stress (10ÿ2 Pa). This corresponds to the stress level exerted on the surrounding medium when gravity acts on micron-sized oil droplets in water. Away from the dilute Stokes limit, the creaming rate is lower because of hydrodynamic interactions between the droplets. Therefore concentrated emulsions are inherently more stable to creaming than dilute emulsions. In fact, creaming becomes inhibited altogether when the oil volume fraction is sufficiently high that the droplets become close-packed (as in mayonnaise). A semi-empirical equation describing the creaming of a moderately concentrated emulsion is

v vS 1 ÿ = k ;

2:8

where vS is the Stokes speed from equation 2.7, is a parameter ( 0:6) approximating the close-packing limit for monodisperse spheres, and k ( 8) is an adjustable parameter. Even though it may not be readily evident to the naked eye, some creaming must inevitably occur during extended quiescent storage of a moderately concentrated emulsion. For instance, Fig. 2.3 shows the oil volume fraction as a function of height in a sample of surfactant-stabilized emulsion (18 vol%


33

Fig. 2.3 Creaming profile of stable surfactant-stabilized emulsion (18 vol% mineral oil, 2 wt% Tween 20, mean droplet size d32 = 0.65 m, height 25 cm) as determined with the Leeds Acoustiscan ultrasonic profiler (Povey, 1998). Oil volume fraction is plotted against height for an unstirred emulsion sample at 30 ëC: , after 3 hours; ·, after 188 hours. (Experimental data of Ma et al. (1994), as supplied by Prof. Macolm Povey.)

mineral oil, 2 wt% Tween 20) containing small droplets (mean droplet diameter 1 m) stored at 30 ëC (Ma et al., 1994). These data were obtained by ultrasound velocity scanning, which is an automated non-invasive technique allowing the determination of the local oil droplet density as a function of height for emulsion samples that are highly opaque (Povey, 1998). The freshly prepared emulsion has a vertically uniform oil content, but after one week of undisturbed storage there is a decrease in near the bottom of the sample tube and a corresponding increase in towards the top. The creaming behaviour shown in Fig. 2.3 is typical of that of a fine, unflocculated, low-viscosity emulsion in the absence of hydrocolloid stabilizer. Emulsion creaming is strongly affected by the state of flocculation. Provided they do not get in each other's way, flocs move faster than individual droplets because of their greater effective size. Hence flocculation increases the creaming rate at low or medium . This effect is amplified by increased polydispersity due to the differential creaming speeds of smaller and larger droplets causing them to approach and associate more often than in a more monodisperse system. In a concentrated emulsion, flocculation tends to retard creaming due to the formation of an extensive network of interconnected flocs which are prevented from readily moving past one another under the influence of gravity. Phase separation may then occur only as a result of rearrangements and consolidation of the gellike structure, with liquid continuous phase being exuded from gaps in the

34


flocculated droplet network by a process of syneresis rather than by conventional droplet creaming. The cross-over volume fraction from the dilute regime (enhanced creaming) to the concentrated regime (retarded creaming) is sensitively dependent on the microstructure of the flocs. 2.2.5 Coalescence The merging of two or more emulsion droplets to form a larger single droplet is called coalescence. In the mouth, during eating, droplet coalescence has a positive role in enhancing flavour release. But coalescence perceived during emulsion storage is invariably considered as highly unacceptable in a food emulsion product. Droplet merging during product storage leads to enhanced creaming due to shifting of the overall distribution towards larger droplet sizes. Coalescence is also more probable for larger droplets, and so the process tends to be self-accelerating, leading on to the formation of a separate layer of free oil (òiling off'). The rate depends on the nature of the interdroplet forces at very close surface±surface separations. Once prepared without bridging flocculation, fine protein-stabilized emulsions are usually impressively stable towards coalescence. When it does occur, the phenomenon is most commonly found in dense cream layers or flocculated systems, especially when the adsorbed protein layer is weakened by the presence of surfactant (emulsifier), and/or when the emulsion is subjected to aeration or intense stirring. Partial coalescence (`clumping') is the process whereby two or more partially crystalline oil droplets join together to form an irregularly shaped aggregate (Boode and Walstra, 1993; Walstra, 1996, 2003). It occurs when a solid fat crystal from one droplet penetrates the liquid oil region of another droplet. Each clump is composed of a continuous network of aggregated fat crystals held together by `necks' of liquid oil. Partial coalescence is influenced by many of the same factors as affect normal coalescence. Two important additional factors are: (i) the temperature cycling of cream layers, which causes growth and melting of fat crystals, and (ii) agitation or stirring, which greatly increases the likelihood of collision-induced crystal penetration between droplets. Partial coalescence is a key mechanism during the churning of cream into butter, and also in the stabilization of air cells during ice-cream manufacture. 2.2.6 Ostwald ripening Ostwald ripening is the growth of larger droplets at the expense of smaller ones due to mass transport of soluble dispersed material through the continuous phase. Because of the moderately high solubility of flavour oils in water, this is an important instability mechanism in soft drink emulsions. Unlike the other main instability mechanisms, Ostwald ripening is relatively insensitive to oil volume fraction or rheology of the continuous phase. The thermodynamic driving force for Ostwald ripening is the increasing


35

chemical potential of a dispersed phase component with decreasing droplet size (Dickinson, 1992; McClements, 2005a). This leads to a greater tendency for dissolution from smaller droplets than from bigger ones. According to the classical Lifshitz±Slezov±Wagner theory, the coarsening rate follows the relationship dhai3 =dt / K S1 D;

2:9

where hai is the mean droplet radius, t is the time, S1 is the thermodynamic solubility of the solute in the continuous phase for a droplet with infinite curvature (a ! 1), D is the diffusion coefficient of the solute in the continuous phase, and K is a characteristic length scale which is proportional to the interfacial tension . Equation 2.9 is strictly applicable to a dilute emulsion under steady-state conditions, where the shape of the droplet-size distribution is independent of time. For such a system, Ostwald ripening may be slowed in various ways: · Increase of droplet size. Because the solubility of dispersed phase increases with decreasing droplet radius, the ripening rate becomes greater the smaller the mean droplet size. Hence the preparation a very fine emulsion ± with the intention of reducing creaming (and flocculation/coalescence) ± is not a successful strategy for ensuring stability if the rate of Ostwald ripening is significant. · Increase in monodispersity. Because the thermodynamic driving force is related to differences in droplet size, the narrower the size distribution, the slower the rate. In theory, a perfectly monodisperse emulsion does not exhibit Ostwald ripening. · Reduction in interfacial tension. Substantial lowering of (e.g., by adding surfactant) may be difficult to achieve in practice without adversely affecting the solubility of the dispersed material in the continuous phase. However, growth or shrinkage of individual droplets can be stopped altogether by the presence of an adsorbed elastic layer which mechanically resists the expansion or compression of the droplet surface area. · Incorporation of insoluble material into dispersed phase. In practice, this is the most successful strategy. Entropy of mixing favours a similar composition for all dispersed droplets. So the mixing of another insoluble (or poorly soluble) component into the dispersed phase reduces the coarsening tendency by providing a large counteracting thermodynamic driving force in direct opposition to the Ostwald ripening effect.

2.3 Effect of non-adsorbing hydrocolloids on emulsion stability A major function of hydrocolloids in food emulsions is to act as a thickening agent of the aqueous medium. The intention is to reduce or inhibit creaming by modifying the rheology of the continuous phase. In addition, the hydrocolloid

36


may impart a desirable texture and smooth mouthfeel to the product. This type of additive is functionally effective at very low concentrations (< 0.5%) due to its high molecular weight and extended macromolecular structure. 2.3.1 Rheology of hydrocolloid solutions The effective hydrodynamic size of a non-gelling hydrocolloid in aqueous solution is indicated by its intrinsic viscosity []. Under highly dilute conditions where the solution is Newtonian, the intrinsic viscosity is defined by limc!0 sp =c;

2:10

where c is the polysaccharide concentration and sp is the specific viscosity, defined as sp r ÿ 1 =s ÿ 1:

2:11

Here r is the relative viscosity, is the viscosity of the hydrocolloid solution, and s is the viscosity of the pure solvent (c 0). The intrinsic viscosity increases with the weight-average molecular weight Mw according to the Mark± Houwink relationship: K 0 Mw ;

2:12

where K 0 and are constants (Tanford, 1961; Launay et al., 1986). For linear flexible polymers in a good solvent (e.g., aqueous solutions of dextran, amylose or locust bean gum), the exponent has a value in the range 0.5±0.8. For highly branched polymers (like amylopectin) the value of a lies below 0.5. Conversely, the value of is greater than unity for stiff linear polymers and polyelectrolytes (especially at low ionic strength). Each flexible polymer molecule in a dilute solution does not interact significantly with the other polymers. But as the polymer content increases, a certain concentration is reached (c c ) beyond which the neighbouring polymer coils begin to overlap. In this semi-dilute solution (c > c ) each individual polymer segment (being mainly surrounded by solvent) `sees' the solution as still dilute, but each whole polymer molecule `sees' the solution as concentrated, since it is entangled with, and hence is interacting with, other polymer molecules in the solution (de Gennes, 1979). Hydrocolloids differ considerably in their values of c . In general, the higher the molecular weight of the polymer, the lower is the overlap concentration. But for the same molecular mass, [] is much smaller for a highly compact branched hydrocolloid like gum arabic than for an extended linear hydrocolloid such as carrageenan. Hence, whereas a 10 wt% gum arabic solution may be regarded as being still dilute (c < c ), a carrageenan solution of 1 wt%, or a xanthan gum solution of only 0.1 wt%, is in the semi-dilute regime (c > c ). With non-gelling hydrocolloids whose flow properties are determined by nonspecific repulsive chain±chain interactions, the relationship between the limiting zero-shear-rate viscosity 0 and the polymer concentration c changes rather


37

Fig. 2.4 Concentration-dependent viscosity of non-gelling hydrocolloid. The logarithm of the specific viscosity sp is plotted against the logarithm of c[], where c is the concentration and [] is the intrinsic viscosity defined by equation 2.10. The cross-over point between the dilute regime (c < c , slope 1.3) and the semi-dilute regime (c > c , slope 3.3) occurs at sp 10 and c 4=.

abruptly at the overlap concentration. That is, when represented as a double logarithmic plot of specific viscosity sp ( _ ! 0) against c, the experimental data fall on a master curve as shown in Fig. 2.4, with straight lines of slopes 1.3 and 3.3 representing the dilute and semi-dilute regimes, respectively (Morris, 1984). The transition point occurs at the concentration c 4=, corresponding to a viscosity of 0 c 10 mPa s (i.e., sp 10). More complex behaviour than that indicated in Fig. 2.4 is found with some hydrocolloids (e.g., guar gum or locust bean gum) whose molecules have gel-like attractive interactions between specific sequences on different chains. In these cases the onset of the semi-dilute regime occurs at lower c and the slope of the log±log plot of sp against c beyond c c is higher. Whereas the dilute solution is (nearly) Newtonian in its flow behaviour, the semi-dilute solution is shear-thinning. The dependence of the apparent viscosity on the shear-rate _ can be described, for instance, by the semi-empirical Cross equation (van Aken, 2006): 1 0 ÿ 1 =1 _ m :

2:13

38


The quantities 0 and 1 are the limiting viscosities at very low and very high shear rates, respectively. The parameter is a characteristic time constant corresponding to the average time of interpenetration/interaction of the deformed coil, and the exponent m has a value of 0.76. The value of increases with the hydrocolloid concentration and the molecular weight. For the hydrocolloid thickener of first choice in food emulsions, i.e., xanthan gum, the value of 0 (as measured at _ 1 sÿ1) is typically several orders of magnitude higher than 1 (as measured at _ 103 sÿ1). This allows the thickened emulsion to flow readily under the moderately high-shear conditions encountered during product formulation, carton filling/emptying and eating. At the same time, the high value of 0 provides the emulsion continuous phase with an extremely viscous environment, which resists the movement of individual droplets against the combined influences of gravity, interdroplet forces and Brownian motion.

2.3.2 Depletion flocculation and serum separation One of the most common types of instability in food O/W emulsions is depletion flocculation caused by the presence of a low concentration of non-adsorbing hydrocolloid. Depletion flocculation is also induced by nanoparticles such as surfactant micelles and casein sub-micelles (Radford and Dickinson, 2004). The depletion contribution to the pair potential U(d) is associated with an osmotic pressure difference between the interdroplet gap region depleted of polymer molecules (or nanoparticles) and the continuous phase beyond the interdroplet gap region. For the idealized case of flocculation of large hard spheres of radius a by small hard spheres of diameter ds, the Asakura±Oosawa depletion potential has the form 8 3 > < ÿ3kTas =ds ds ÿ d; d < ds 2:14 Ud d > : 0; d ds where s is the volume fraction of the small spheres. The interaction is relatively weak. For instance, for two emulsion droplets of radius a 0:5 m in a solution containing nanoparticles of diameter ds 10 nm at a concentration of s 0:02 (i.e., 2 vol%), equation 2.14 gives a maximum depletion attraction at contact (d 0) of Ud ÿ3kT. The depletion interaction arising from flexible non-adsorbed polymers is greater than that from spherical nanoparticles because the configurational entropy of the chains is substantially reduced near the particle surface (Vincent et al., 1986). A useful theoretical expression is Ud d ÿ2a ÿ 12 d1 2=3a d=6a;

2:15

where is the osmotic pressure of the polymer solution. The quantity is the depletion layer thickness, which is approximately equal to the radius of gyration of the polymer in the dilute regime. Dilution of the continuous phase with


39

solvent leads to lowering of and hence Ud(d), which means that this type of weak flocculation is completely reversible with respect to dilution by the continuous phase. Therefore its presence is not detectable with the conventional light-scattering equipment (e.g., Malvern Mastersizer) used for routine dropletsize analysis. Depletion flocculation can have an enormous effect on creaming stability (Dickinson, 1993, 2003, 2004). At very low hydrocolloid concentrations, the entropy loss linked to droplet association outweighs the depletion effect and so the system remains stable. Beyond a certain critical concentration, however, the presence of depletion flocculation is manifest in rapid serum separation. Due to their large excluded volumes, polysaccharides with stiff extended backbones (e.g., xanthan gum) are especially effective at inducing depletion flocculation. Figure 2.5 shows the influence of various concentrations of xanthan on the plot of serum layer thickness against time for samples of sodium caseinate-stabilized emulsions (10 vol% oil, 0.5 wt% protein, pH 7) stored quiescently at 25 ëC in glass tubes of height 10 cm (Cao et al., 1990). The reference emulsion without added xanthan shows no visible serum separation over the storage period of 72 h, but the presence of just 0.025 or 0.05 wt% xanthan is sufficient to induce rapid serum separation (complete within 1±2 h) of the low-viscosity liquid-like

Fig. 2.5 Influence of xanthan gum on creaming of protein-stabilized emulsion (10 vol% oil, 0.5 wt% sodium caseinate, pH = 7, ionic strength = 0.005 M, total sample height = 10 cm). Serum layer height H is plotted against storage time t at 25 ëC for various polysaccharide concentrations: t, 0 wt% and 0.125 wt%; l, 0.025 wt%; , 0.05 wt%; ú, 0.065 wt%; 4, 0.1 wt%. (Reproduced with permission from Cao et al., 1990.)

40


emulsion, with the serum (non-cream) layer occupying 65±70% of the sample volume. At 0.0625 wt% xanthan, the same degree of phase separation takes 48 h; at 0.1 wt% xanthan, there is only 10% serum separation after 72 h; and, at 0.125 wt% xanthan, the system is as stable as in the absence of xanthan. Inhibition of creaming at high xanthan concentrations is conventionally attributed to the immobilization of the emulsion droplets in a weak gel-like network (very high 0 ). Figure 2.6 shows creaming profiles (volume fraction vs height) for a surfactant-stabilized emulsion (18 vol% oil, 2 wt% Tween 20) containing 0.17 wt% xanthan (Ma et al., 1994). The data were obtained by ultrasound velocity scanning on the same emulsion system (no added salt) as that shown in Fig. 2.3. The sample shows no change in oil content for several hours, but after 1 day there evolves a pronounced continuous gradient in from the bottom to the top of the sample. After 2 days there is a distinct boundary at height 150 mm between a lower emulsion phase ( 0:05±0.1) and an upper emulsion phase ( 0:35±0.4). After 4 days the lower serum has become completely depleted of oil droplets, and after 1 week the upper cream layer has reached an oil content equivalent to close-packed monodisperse hard sphere ( 0:63). For more concentrated emulsions (say, 0:3), the change in emulsion creaming behaviour caused by addition of non-adsorbing polysaccharide tends to correlate better with the rheology of the emulsion as a whole, rather than with

Fig. 2.6 Creaming of surfactant-stabilized emulsion (18 vol% mineral oil, 2 wt% Tween 20, mean droplet size d32 = 0.65 m, height 25 cm) containing 0.17 wt% xanthan (low ionic strength). Oil volume fraction is plotted against height for an unstirred emulsion sample at 30 ëC: , after 11 h; s, after 20 h; , after 30 h; n, after 45 h; ú, after 99 h; l, after 188 h. (Experimental data of Ma et al. (1994), as supplied by Prof. Macolm Povey.)


41

the rheology of the hydrocolloid solution making up the continuous phase (Dickinson, 2003, 2004). This implies that stability is controlled by the properties of the long-lasting metastable network of flocculated droplets held together by the short-range depletion interactions induced by the added hydrocolloid (Parker et al., 1995; Dickinson, 2006). A manifestation of the early stages of the system's evolution is phase separation on the microscopic scale. This phenomenon can be considered to be somewhat analogous to the phase separation observed in mixed solutions of two polymers exhibiting thermodynamic incompatibility (Tolstoguzov, 1991). Figure 2.7 shows some microscopic images of a caseinate-based emulsion (30 vol% oil, 1.4 wt% protein, pH = 7, mean droplet size 0:5 m) containing

Fig. 2.7 Influence of xanthan gum on microstructure of protein-stabilized emulsion (30 vol% oil, 1.4 wt% sodium caseinate, pH = 7, mean droplet size d32 ~ 0.5 m). Confocal images (250 250 m) were captured 10 minutes after sample stirring had stopped. Polysaccharide concentrations in the aqueous phase: (a) 0.01, (b) 0.02, (c) 0.04 and (d) 0.1 wt%. (Reproduced with permission from Moschakis et al., 2005.)

42


various concentrations of xanthan in the aqueous phase (Moschakis et al., 2005). The images were recorded 10 minutes after stopping stirring. We can see microscopic phase separation into separate oil-rich and xanthan-rich regions, the latter appearing as dark blobs against the lighter background. In the hydrocolloid concentration range 0.02±0.05 wt%, the samples were observed to exhibit complex dynamic behaviour, including blob shape relaxation processes, microstructural coarsening and microphase coalescence phenomena. The elongated shapes of the xanthan-rich domains arise from the hydrodynamic shear forces applied during sample preparation and mixing. Once stirring ceases, the interfacial tension drives the blob shape towards spherical at a rate which sensitively depends on the viscoelastic properties of the blob and its surrounding local environment. The blob shape relaxation time is a strongly increasing function of xanthan content. For the system illustrated in Fig. 2.7, no microstructural evolution was observed over the experimental time-scale (several hours) for xanthan concentrations above 0.06 wt%. Analysis of the diffusion coefficient of individual probe particles has demonstrated that, in this low polysaccharide concentration range, the effective viscosity of the oil-droplet-rich regions is up to 103 times larger than that of the coexisting xanthan-rich regions (Moschakis et al., 2006). Furthermore, the inferred low-stress viscosity of the flocculated oildroplet-rich region increases dramatically with the xanthan concentration. So, as a result of changes in microstructure and microrheology caused by the hydrocolloid addition, the original liquid-like protein-stabilized emulsion is transformed into a stable, concentrated, viscoelastic emulsion containing `blobs' of hydrocolloid-structured water.

2.4

Effect of adsorbing hydrocolloids on emulsion stability

2.4.1 Hydrocolloid emulsifying agents Any hydrocolloid that is substantially surface-active has the potential for acting as both an emulsifying agent and a stabilizing agent. The effectiveness of the emulsifying agent is related to the minimum amount of it that is required to generate and stabilize small droplets during homogenization. A useful quantity in this context is the surface load, i.e., the mass of emulsifying agent per unit area of oil±water interface (typically a few mg mÿ2). The mass adsorbed per unit volume of emulsion (Cs) is equal to the initial concentration of emulsifying agent minus that remaining in the aqueous phase after homogenization, as determined following centrifugation or filtration. The surface load ÿ is calculated from ÿ Cs d32 =6;

2:16

where d32 is the volume±surface mean diameter. Knowledge of the surface load enables the calculation of the minimum amount of emulsifying agent required to prepare an emulsion of known volume fraction and droplet size. For the milk protein -casein, the theoretical minimum amount lies quite close to the amount


43

actually needed in practice. But for a less efficient emulsifier (e.g., gum arabic) a substantial excess of emulsifying ingredient is required in order to achieve the desired effect. The reason for this is that the gum is a complex mixture of polymers, and not all of the macromolecular species are capable of adsorbing and stabilizing the interface (Randall et al., 1988). Moreover, even those fractions of the gum that are capable of adsorbing do not necessarily have time to do so during the very rapid process of high-pressure homogenization (10ÿ4 s). Consequently, when employing gum arabic as emulsifying agent, it is necessary to use a rather high gum/oil ratio (1:1) in order to produce fine stable emulsion droplets (d32 1 m) (McNamee et al., 1998). Even though acacia gums typically contain just a few per cent protein, this fraction seems to play a crucial role in terms of the interfacial functionality (Dickinson et al., 1988; Dickinson, 2003). For acacia gums of variable nitrogen content, there is a good correlation between the protein content and the steady-state interfacial tension at the oil±water interface, and also between the emulsifying capacity and the rate of change of tension with time. However, the nitrogen content alone is not a reliable indicator of the effectiveness of acacia gums for emulsification. Other factors also appear to be important, such as the average molecular weight of the carbohydrate polymers, and the distribution of the proteinaceous fraction amongst the different sized polymer species. The special emulsifying and stabilizing properties of gum arabic (Acacia senegal) is associated with a high-molecular-weight fraction representing less than 30% of the total hydrocolloid (Randall et al., 1988, 1989; Ray et al., 1995). The protein is covalently bound to the carbohydrate in the form of a mixture of arabinogalactan±protein complexes each containing several highly branched polysaccharide units linked to a common protein core. The protein chain firmly anchors the complex to the oil±water interface, and the charged polysaccharide units attached to the protein chain provide a barrier against flocculation and coalescence. Gum arabic is a polyelectrolyte, and so the emulsion droplets carry a net negative charge under beverage emulsion conditions. However, the value of the zeta potential is rather low (10±20 mV), indicating that the main stabilization mechanism is steric in character. Certain types of pectin have also been shown to be effective for making emulsions. Again the interfacial functionality is mainly attributed to the presence of bound protein. In the case of citrus pectin, the accessibility of the protein fraction for adsorption at the oil±water interface can be substantially enhanced by depolymerization (Akhtar et al., 2002). Whereas for citrus or apple pectin the bound fraction of protein is low (1.5±3%), it is significantly higher (up to 10%) for sugar beet pectin. In fact, due to its higher protein content, sugar beet pectin is even more surface-active than gum arabic, being effective in stabilizing fine emulsions at the relatively low emulsifier/oil ratio of 1:10 (Williams et al., 2005).

44


2.4.2 Protein±polysaccharide interactions: conjugates and complexes In searching for a replacement for the expensive and occasionally scarce gum arabic, there has been a move towards preparing composite protein±polysaccharide emulsifiers by alternative methods. One straightforward and practical way to achieve conjugation of protein with polysaccharide is by using the Amadori rearrangement steps in the Maillard reaction carried out under controlled dry-heating conditions (Kato et al., 1990; Dickinson and Galazka, 1991). During this complex sequence of reactions, the terminal and side-chain amine groups on the protein become linked to the reducing end of the polysaccharide. Conjugation of carbohydrate to protein improves solubility under unfavourable solution conditions of low pH and high ionic strength, with consequent benefits for protein emulsification properties. For instance, a whey protein±maltodextrin conjugate made from commercial whey protein isolate and maltodextrin (molecular weight ~ 104 Da) can produce fine emulsion droplets (< 1 m) with triglyceride oil or orange oil under neutral or acidic conditions. As a possible replacement for gum arabic, the protein±polysaccharide conjugate emulsifier can be used at relatively low emulsifier/oil ratios to prepare low-pH beverage-type emulsions with a shelf-life of several weeks. Furthermore, in contrast to the corresponding emulsion based on protein alone, the conjugatebased formulation exhibits no precipitation or phase separation on mixing with colouring agents, either before or after extensive dilution (Akhtar and Dickinson, 2007). Polysaccharides can form various types of physical complexes with proteins depending on the pH, the ionic strength, and the biopolymer charge distributions. The formation of such complexes implies the dominance of short-ranged attractive forces. Attractive protein±polysaccharide interactions may be strong (long-lasting) or weak (reversible). These non-specific protein±polysaccharide interactions arise as a result of averaging in time and space over all the individual specific chemical interactions (ionic, hydrogen bonding, hydrophobic, etc.) on the different macromolecules (Dickinson, 1998). Electrostatic forces are especially important at low ionic strength, and complete dissociation of complexes usually occurs on addition of excess electrolyte. Strong attractive electrostatic interactions are typically found with positively charged proteins (pH < pI) and negatively charged polysaccharides. Weaker reversible complexes tend to be formed between uncharged (pH pI) or negatively charged proteins (pH > pI) and anionic polysaccharides. On adjustment of pH and/or electrolyte concentration, the net protein±polysaccharide interaction may change substantially, even switching from net attractive to net repulsive. Some hydrocolloids can achieve interfacial functionality during or after emulsion formation by forming an associative interaction with an adsorbed protein layer. Whilst the charged polysaccharide by itself is not surface-active, the electrostatic complex of protein + polysaccharide has a strong tendency to adsorb at the oil±water (or air±water) interface (Dickinson, 1995, 1998). The overall effect of the interacting polysaccharide on the emulsion stability and microstructure is dependent on the concentration of added polymer, as illu-


45

Fig. 2.8 Schematic representation of the effect of attractive protein±polysaccharide interactions on a protein-stabilized emulsion: (a) no added polysaccharide; (b) bridging flocculation at low polysaccharide concentration; (c) steric stabilization of droplets with saturated coverage of polysaccharide; (d) emulsion gel with droplets immobilized in entangled polysaccharide network.

strated schematically in Fig. 2.8. Addition of a small amount of polymer to an initially stable emulsion (a) leads to bridging flocculation (b). When sufficient polymer is present to saturate the droplet interface, the emulsion is stabilized electrostatically by the secondary layer of charged polysaccharide (c). And when the hydrocolloid content in the aqueous phase is sufficiently high (c > c ), the emulsion droplets may be immobilized in a polymer gel network (d). All these stages of (in)stability behaviour have been reported (Dickinson and Pawlowsky, 1997) for emulsions based on bovine serum albumin (BSA) at pH 6 and low ionic strength in the presence of various concentrations of -carrageenan, a sulfated polysaccharide of high charge density. Direct experimental evidence of the presence of protein±polysaccharide interactions at the oil±water interface

46


can be readily indicated by surface rheological measurements (Dickinson and Galazka, 1992; Dickinson et al., 1998). The structure of any composite interfacial layer comprising both protein and polysaccharide depends to some extent on the procedure used to make the emulsion. One way is to prepare a mixed solution of the biopolymers, and then use the protein±polysaccharide complex as the emulsifying agent during homogenization. The alternative approach involves first preparing the emulsion with protein as the emulsifying agent, and afterwards adding the interacting polysaccharide to the aqueous phase to produce an emulsion containing droplets coated with a protein±polysaccharide bilayer. The so-called `layer-by-layer' approach has attracted much attention recently because of its potential for encapsulation technology and its success in protecting emulsions against severe environmental stresses (Guzey and McClements, 2007). In practice, though, it is not straightforward to use the layer-by-layer approach to make fine stable emulsions containing adsorbing hydrocolloids. A major issue is the tendency for extensive flocculation even under conditions where the protein surface should be saturated with polysaccharide (McClements, 2005b). Bridging flocculation occurs when the polysaccharide content is such that droplet collisions occur faster than the rate of polysaccharide saturation of the protein-coated droplet surface, and depletion flocculation and/or gelation may occur if the system contains too high a concentration of unadsorbed polysaccharide. Typically, with intense mechanical agitation and a low oil content ( 0:05±0.1), there is a window of polysaccharide concentrations within which fine stable emulsions can be prepared. But for high oil contents, even with vigorous agitation, there is no useful range of polysaccharide content over which unflocculated emulsions are accessible. For this reason, it can be more convenient to prepare emulsions containing protein±polysaccharide complexes by simply mixing together the two biopolymer ingredients in the aqueous phase prior to homogenization (Dickinson et al., 1998; Jourdain et al., 2008).

2.5

Summary

The stability and acceptability of liquid-like oil-in-water emulsions is influenced by a number of mechanistic processes: creaming, flocculation, (partial) coalescence and Ostwald ripening. These processes are closely interrelated. In particular, the creaming stability is very sensitively correlated to the state of flocculation. In physico-chemical terms the properties of an individual emulsion are determined by the structure of the adsorbed layer, which in turn influences the nature of the interaction pair potential between the dispersed droplets. The two main stabilization mechanisms are electrostatic and steric. The basic theory underlying these two mechanisms gives useful practical insight concerning the design of emulsifier properties and the emulsion conditions favouring long-term stability.


47

Whilst food proteins are typically the primary emulsifying ingredients, a few surface-active hydrocolloids can also act as effective emulsifying agents. More generally, added hydrocolloids affect emulsion stability by modifying the viscosity and non-Newtonian rheology of the continuous phase. The presence of low concentrations of non-adsorbing hydrocolloids leads to depletion flocculation, microscopic phase separation and macroscopic serum separation. Whilst the association of polysaccharides with adsorbed protein can be a source of unwanted bridging flocculation, under optimized conditions these same interactions in electrostatic protein±polysaccharide complexes can also be used to improve emulsion stability.

2.6

References

and DICKINSON, E. (2007) `Whey protein±maltodextrin conjugates as emulsifying agents: an alternative to gum arabic', Food Hydrocolloids, 21, 607± 616. AKHTAR, M., DICKINSON, E., MAZOYER, J. and LANGENDORFF, V. (2002) Èmulsion stabilizing properties of depolymerized pectin', Food Hydrocolloids, 16, 249±256. BOODE, K. and WALSTRA, P. (1993) `The kinetics of partial coalescence in oil-in-water emulsions', in Dickinson, E. and Walstra, P., Food Colloids and Polymers: Stability and Mechanical Properties, Cambridge, Royal Society of Chemistry, pp. 23±30. CAO, Y., DICKINSON, E. and WEDLOCK, D. J. (1990) `Creaming and flocculation in emulsions containing polysaccharide', Food Hydrocolloids, 4, 185±195. DAMODARAN, S. (2005) `Protein stabilization of emulsions and foams', Journal of Food Science, 70, R54±R66. DE GENNES, P.-G. (1979) Scaling Concepts in Polymer Physics, Ithaca, NY, Cornell University Press. DICKINSON, E. (1992) An Introduction to Food Colloids, Oxford, Oxford University Press. DICKINSON, E. (1993) `Protein±polysaccharide interactions in food colloids', in Dickinson, E. and Walstra, P., Food Colloids and Polymers: Stability and Mechanical Properties, Cambridge, Royal Society of Chemistry, pp. 77±93. DICKINSON, E. (1995) Èmulsion stabilization by polysaccharides and protein± polysaccharide complexes', in Stephen, A. M., Food Polysaccharides and their Applications, New York, Marcel Dekker, pp. 501±515. DICKINSON, E. (1998) `Stability and rheological implications of electrostatic milk protein± polysaccharide interactions', Trends in Food Science and Technology, 9, 347±354. DICKINSON, E. (2003) `Hydrocolloids at interfaces and the influence on the properties of dispersed systems', Food Hydrocolloids, 17, 25±39. DICKINSON, E. (2004) Èffect of hydrocolloids on emulsion stability', in Williams, P. A. and Phillips, G. O., Gums and Stabilisers for the Food Industry ± 12, Cambridge, Royal Society of Chemistry, pp. 394±404. DICKINSON, E. (2006) `Colloid science of mixed ingredients', Soft Matter, 2, 642±652. DICKINSON, E. and GALAZKA, V. B. (1991) Èmulsion stabilization by ionic and covalent complexes of -lactoglobulin with polysaccharides', Food Hydrocolloids, 4, 281± 296. AKHTAR, M.

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and GALAZKA, V. B. (1992) Èmulsion stabilization by protein/polysaccharide complexes', in Phillips, G. O., Wedlock, D. J. and Williams, P. A., Gums and Stabilisers for the Food Industry ± 6, Oxford, IRL Press, pp. 351±362. DICKINSON, E. and PAWLOWSKY, K. (1997) Èffect of -carrageenan on flocculation, creaming and rheology of a protein-stabilized emulsion', Journal of Agricultural and Food Chemistry, 45, 3799±3806. DICKINSON, E. and STAINSBY, G. (1982) Colloids in Food, London, Applied Science. DICKINSON, E., MURRAY, B. S., STAINSBY, G. and ANDERSON, D. J. (1988) `Surface activity and emulsifying behaviour of some Acacia gums', Food Hydrocolloids, 2, 477±490. DICKINSON, E., SEMENOVA, M. G., ANTIPOVA, A. S. and PELAN, E. G. (1998) Èffect of highmethoxy pectin on properties of casein-stabilized emulsions', Food Hydrocolloids, 12, 425±432. EVANS, D. F. and WENNERSTROM, H. (1994) The Colloidal Domain, New York, WileyVCH. È BLOM, J. (EDS) (2004) Food Emulsions, 4th edn, New FRIBERG, S. E., LARSSON, K. and SJO York, Marcel Dekker. GUZEY, D. and MCCLEMENTS, D. J. (2007) `Formation, stability and properties of multilayer emulsions for application in the food industry', Advances in Colloid and Interface Science, 128±130, 227±248. HIEMENZ, P. C. and RAJAGOPALAN, R. (1997) Principles of Colloid and Surface Chemistry, 3rd edn, New York, Marcel Dekker. HUNTER, R. J. (1986) Foundations of Colloid Science, vol. 1, Oxford, Oxford University Press. JOURDAIN, J., LESER, M. E., SCHMITT, C., MICHEL, M. and DICKINSON, E. (2008) `Stability of emulsions containing sodium caseinate and dextran sulfate: relationship to complexation in solution', Food Hydrocolloids, 22, 647±659. KATO, A., SASAKI, Y., FURUTA, R. and KOBAYASHI, K. (1990) `Functional protein/ polysaccharide conjugate prepared by controlled dry heating of ovalbumin/dextran mixtures', Agricultural and Biological Chemistry, 54, 107±112. LAUNAY, B., DOUBLIER, J. L. and CUVELIER, G. (1986) `Flow properties of aqueous solutions and dispersions of polysaccharides', in Mitchell, J. R. and Ledward, D., Functional Properties of Food Macromolecules, London, Elsevier Applied Science, pp. 1±78. LEAL-CALDERON, F. L., SCHMITT, V. and BIBETTE, J. (2007) Emulsion Science: Basic Principles, 2nd edn, New York, Springer. MA, J., DICKINSON, E. and POVEY, M. J. W. (1994) `Creaming of concentrated oil-in-water emulsions containing xanthan', Food Hydrocolloids, 8, 481±497. MCCLEMENTS, D. J. (2005a) Food Emulsions, 2nd edn, Boca Raton, FL, CRC Press. MCCLEMENTS, D. J. (2005b) `Theoretical analysis of factors affecting the formation and stability of multilayered colloidal dispersions', Langmuir, 21, 9777±9785. MCCLEMENTS, D. J. (2007) `Critical review of techniques and methodologies for characterization of emulsion stability', Critical Reviews in Food Science and Nutrition, 47, 611±649. MCNAMEE, B. F., O'RIORDAN, E. A. and O'SULLIVAN, M. (1998) Èmulsification and encapsulation properties of gum arabic', Journal of Agricultural and Food Chemistry, 46, 4551±4555. MORRIS, E. R. (1984) `Rheology of hydrocolloids', in Phillips, G. O., Wedlock, D. J. and Williams, P. A., Gums and Stabilisers for the Food Industry 2, Oxford, Pergamon, pp. 57±78. MOSCHAKIS, T., MURRAY, B. S. and DICKINSON, E. (2005) `Microstructural evolution of DICKINSON, E.


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viscoelastic emulsions stabilized by sodium caseinate and xanthan gum', Journal of Colloid and Interface Science, 284, 714±728. MOSCHAKIS, T., MURRAY, B. S. and DICKINSON, E. (2006) `Particle tracking using confocal microscopy to probe the microrheology in a phase-separating emulsion', Langmuir, 22, 4710±4719. PARKER, A., GUNNING, P. A., NG, K. and ROBINS, M. M. (1995) `How does xanthan stabilize salad dressing?', Food Hydrocolloids, 9, 333±342. POVEY, M. J. W. (1998) Ùltrasonics of food', Contemporary Physics, 39, 467±478. RADFORD, S. J. and DICKINSON, E. (2004) `Depletion flocculation of caseinate-stabilized emulsions: what is the optimum size of the non-adsorbed protein nano-particles?', Colloids and Surfaces A, 238, 71±81. RANDALL, R. C., PHILLIPS, G. O. and WILLIAMS, P. A. (1988) `The role of the proteinaceous component on the emulsifying properties of gum arabic', Food Hydrocolloids, 2, 131±140. RANDALL, R. C., PHILLIPS, G. O. and WILLIAMS, P. A. (1989) `Fractionation and characterization of gum from Acacia senegal', Food Hydrocolloids, 3, 65±75. RAY, A. K., BIRD, P. B., IACOBUCCI, G. A. and CLARK, B. C., JR (1995) `Functionality of gum arabic: fractionation, characterization and evaluation of gum fractions in citrus oil emulsions and model beverages', Food Hydrocolloids, 9, 123±131. TAN, C.-T. (2004) `Beverage emulsions', in Friberg, S. E., Larsson, K. and Sjo È blom, J., Food Emulsions, 4th edn, New York, Marcel Dekker, pp. 485±524. TANFORD, C. (1961) Physical Chemistry of Macromolecules, New York, Wiley. TOLSTOGUZOV, V.B. (1991) `Functional properties of food proteins and role of protein± polysaccharide interaction', Food Hydrocolloids, 4, 429±468. VAN AKEN, G. A. (2006) `Polysaccharides in food emulsions', in Stephen, A. M., Phillips, G. O. and Williams, P. A., Food Polysaccharides and their Applications, 2nd edn, Boca Raton, FL, CRC Press, pp. 531±539. VINCENT, B., EDWARDS, J., EMMETT, S. and JONES, A. (1986) `Depletion flocculation in dispersions of sterically stabilized particles (``soft spheres'')', Colloids and Surfaces, 18, 261±281. WALSTRA, P. (1996) `Disperse systems: basic considerations', in Fennema, O. R., Food Chemistry, 3rd edn, New York, Marcel Dekker, chap. 3. WALSTRA, P. (2003) Physical Chemistry of Foods, New York, Marcel Dekker. WILLIAMS, P. A., SAYERS, C., VIEBKE, C., SENAN, C., MAZOYER, J. and BOULENGUER, P. (2005) Èlucidation of the emulsification properties of sugar beet pectin', Journal of Agricultural and Food Chemistry, 53, 3592±3597.

3 The health aspects of hydrocolloids C. A. Edwards and A. L. Garcia, University of Glasgow, UK

Abstract: The health effects of hydrocolloids are dependent on how they are incorporated into food. The contribution of each hydrocolloid is small and the health benefits of these compounds cannot be separated from those of other non-digestible carbohydrates. The impact of hydrocolloids on gastric emptying and small intestinal digestion and absorption is well established. More recent work has explored new sources and their mechanisms of action related to their fermentation to short chain fatty acids and their impact on the intestinal microbiota along with potential actions the short chain fatty acids may have on plasma lipids and satiety. This is of increasing importance given the current global epidemic in obesity. Key words: food hydrocolloids, dietary fibre, health, fermentation, short chain fatty acids, plasma lipids, satiety.

3.1

Introduction

The health effects of food hydrocolloids are dependent on how they are incorporated into foods and in the diet. There are many hydrocolloid carbohydrates naturally present in plant foods as part of the cell wall, such as hemicelluloses and pectin, or with other more specific roles within the plant such as storage polysaccharides like guar gum, exudates like gum acacia, and husk polysaccharides such as ispaghula. There are also alginates and bacterially produced hydrocolloids such as gellan and xanthan. However, the contribution of each individual hydrocolloid in the diet is small and epidemiological studies cannot identify and separate the health benefits of these compounds from those of other non-digestible carbohydrates such as insoluble non-starch polysaccharides, resistant starch and oligosaccharides. Hydrocolloids can also be incorporated in small amounts into food products

The health aspects of hydrocolloids

51

as stabilisers, emulsifiers and fat substitutes. Guar gum levels of 100 > 100 50 52 60 70 82 89 > 100

particular, calcium, in solution will inhibit the hydration of LA gellan gum as shown in Table 9.1. It is therefore necessary, in most circumstances, to use a sequestrant to bind the soluble calcium and so aid hydration. Typically, between 0.1 and 0.3% of a sequestrant such as sodium citrate is sufficient to allow complete hydration at 90±95 ëC in water of up to 600 ppm as CaCO3 water hardness. Incomplete hydration will result if the sodium ion concentration exceeds 0.5% (approximately 1.3% sodium chloride). Once the gum is hydrated, additional ions can be added to the hot solution and, provided the temperature is maintained above the gelation temperature, no gel will form. Table 9.2 provides details of the effects of the sequestrant sodium citrate on the hydration temperature of LA gellan gum and shows that hydration can be achieved at temperatures ranging from room temperature to boiling point. Table 9.3 lists the relative sequestering power and effective pH ranges of a number of commonly used sequestrants. In foods containing sugar, LA gellan gum should be hydrated in water and any sugars can be added to the hot gum solution. However, LA gellan gum can be hydrated directly in sugar solutions up to 80 total soluble solids (tss) by heating to boiling. In some cases a low level of sequestrant such as sodium Table 9.2

Effect of sodium citrate on the hydration of 0.25% LA gellan gum

Water hardness (ppm CaCO3) 0 100 300 600 900

Sodium citrate (%)

Hydration temperature (ëC)

0.00 0.05 0.10 0.20 0.40

75 25 65 65 68

208


Table 9.3

Relative sequestering power of sequestrants commonly used in foods

Sequestrant

Sodium hexametaphosphate Tetra sodium diphosphate Di sodium orthophosphate Tri sodium citrate dihydrate

Parts of sequestrant required to sequester 1 part of available calcium pH6

pH4

7 10 130 20

7 20 180 40

citrate (less than 0.3%) is required to bind the free calcium often present in sugar syrups. LA gellan gum will not fully hydrate below pH 3.9. In this case, the acid should be added, preferably as a concentrated solution, to the hot gum solution. Prolonged heating in acidic conditions should be avoided as this leads to some hydrolytic degradation of the gum resulting in a reduction in the quality of the final gel. However, at pH 3.5, LA gellan gum can be held for up to 1 h at 80 ëC with only a minimal loss in gel quality. In neutral conditions solutions can be held at 80 ëC for several hours. LA gellan gum is readily dispersible in milk and reconstituted milk systems and will hydrate upon heating to approximately 80 ëC without the need for a sequestrant. High acyl gellan gum The hydration of HA gellan gum is much less dependent on the concentration of ions in solution than LA gellan gum and generally heating to 85±95 ëC is sufficient to fully hydrate the gum in both water or milk systems. As a dispersion of HA gellan gum is heated, it swells rapidly at approximately 40±50 ëC to form a thick, pasty suspension. With continued heating the suspension loses viscosity suddenly at approximately 80±90 ëC signifying complete hydration. The swelling stage can be avoided by adding the gum directly to hot water (>80 ëC) with the aid of a dispersant such as sugar, oil or glycerol, as described in the previous section. The hydration of HA gellan gum is inhibited by the presence of sugars; therefore it is recommended to hydrate the gum in less than 40% tss. Additional sugar can then be added to the hot gum solution. As with LA gellan gum, HA gellan gum will not hydrate below pH 4.0. Similar care must also be taken under hot acidic conditions to avoid hydrolytic breakdown and loss of gel quality. 9.4.3 Gelation The proposed gelation mechanism of gellan gum is based on the domain model which assumes the formation of distinct junction zones and disordered flexible polymer chains connecting adjacent junction zones.9 As a hot solution cools, gellan gum undergoes a disorder±order transition. This transition has been

Gellan gum

209

attributed to a coil-helix transition.10 In the case of LA gellan gum, gel promoting cations such as sodium, potassium, calcium and magnesium promote aggregation of the gellan double helices to form a three-dimensional network and the subsequent gels are hard and brittle. Recent studies using atomic force microscopy have challenged this and proposed a fibrous model in which network structures develop through the formation of non-associated fibres or strands via either elongation or branching.11 The acyl substituents have a profound effect on the structure and rheological characteristics of gellan gum gels. The gellan gum undergoes a similar disorder to order transition as the solution is cooled but according to the domain model further aggregation of the helices is limited by the presence of the acetyl group.8 According to the fibrous model the acyl groups inhibit end-to-end type intermolecular associations through a type of steric hindrance, resulting in a decrease in the degree of continuity and homogeneity of the gelled system.11 The subsequent gels of HA gellan gum are therefore soft and elastic. Low acyl gellan gum The easiest and most common method of making LA gellan gum gels is to cool hot solutions. LA gellan gum forms gels with a wide variety of cations, notably calcium (Ca2+), magnesium (Mg2+), sodium (Na+), and potassium (K+) as well as acid (H+).10,12 Divalent cations are more efficient at promoting gelation of LA gellan gum than monovalent ions. Gel strength increases with increasing ion concentration until a maximum is reached. Further addition of ions results in a reduction of gel strength due to the òver conversion' of the LA gellan gum with excess ions. Ion concentrations for optimum gelation are generally independent of gum concentration but are reduced as the level of sugar is increased. Figure 9.2 compares the effect of both mono- and divalent ions on the modulus of 0.5% LA gellan gum gels in water and in 60% sucrose. Below pH 3.0 LA gellan gum is able to form a gel without the need for mono- or divalent metal ions. Optimum gel modulus occurs for these acid gels at approximately pH 2.8±3.0 regardless of the acid used. This optimum is not affected by the presence of sugars to the same extent as ion requirements. For example, in the presence of 60% sucrose the optimum shifts to approximately pH 2.5±2.7. Acid gels are generally stronger than ion mediated gels in both water and sugar. Addition of other gelling ions, such as sodium or calcium, generally results in a reduction in gel strength of the acid gels. Gel properties at optimum conditions for LA gellan gum gels in water and 60% sucrose are summarised in Tables 9.4 and 9.5 respectively. In many instances addition of gelling ions is not necessary since there are sufficient ions present in the water or other ingredients to promote gelation of the LA gellan gum. When required, the gel promoting ions can be added to the hot gum solution and, provided the solution is kept above its setting temperature, no gel will form. This allows for the easy preparation of stock solutions (1±2% gum) which can be held at high temperature until required. LA gellan gum is often described as having a 'snap set' since gelation is very rapid once the setting temperature is reached. As with hydration temperature, setting and

210


Fig. 9.2 Effect of calcium (squares), sodium (triangles) and potassium (circles) ion concentration on the modulus of 0.5% LA gellan gum gels in water (open symbols) and 60% sucrose (closed symbols). Table 9.4 Properties of 0.5% LA gellan gum gels in optimum conditions for gel formation in water Gelling ion

Ion concentration (mM)

Modulus (Ncmÿ2)

Brittleness (%)

Setting temperature (ëC)

Calcium Sodium Potassium Acid

8±10 260±300 240±260 pH2.8±3.0

19.3 12.3 12.1 20.3

28.5 28.2 30.0 27.7

42 54 59 10

Table 9.5 Properties of 0.5% LA gellan gum gels in optimum conditions for gel formation in 60% sucrose Gelling ion Calcium Sodium Potassium Acid

Ion concentration (mM) 0.5±1.0 25±35 8±10 pH2.5±2.7

Modulus (Ncmÿ2)

Brittleness (%)

Setting temperature (ëC)

1.66 3.13 1.71 7.74

61.5 54.1 65.6 43.9

38 47 43 64

Gellan gum

211

melting temperatures of the gels depend on the ion concentration in solution. The higher the ion concentration, the higher the setting and melting temperature. Significant thermal hysteresis between the setting and melting temperature is observed in LA gellan gum gels, i.e., the gels melt at a higher temperature than that at which they set.13 In most conditions LA gellan gum gels are not thermally reversible below 100 ëC. The exceptions are gels formulated with a low level of monovalent ions, particularly potassium, and milk gels. Setting time is governed by the rate at which heat is removed which, in turn, depends on the dimensions of the system being cooled. Thin films on a cold surface, for example, set almost instantaneously. Once set, gel strength does not change markedly over time. LA gellan gum is capable of forming self supporting gels at concentrations as low as 0.05% gum. LA gellan gum gels do not synerise unless cut or broken. High acyl gellan gum As with LA gellan gum the easiest way to form HA gellan gum gels is to cool hot solutions. Addition of cations is not necessary for the formation of HA gellan gum gels and their properties are much less dependent on the concentration of ions in solution. Gels typically set and melt between 70 and 80 ëC and show no thermal hysteresis, i.e., they melt at the same temperature at which they set. The setting temperature increases with increasing cation concentration. For example, the temperature increases from approximately 71 ëC to 80 ëC as the calcium increases from 2 to 80 mM. A similar increase is seen when sodium or potassium concentration is increased from 10 to 200 mM.14 HA gellan gum is capable of forming self supporting gels at concentrations above approximately 0.2% gum. HA gellan gum gels do not synerise. 9.4.4 Texture of gellan gum Texture is generally regarded as a multifarious property.15 Texture profile analysis (TPA) is a technique based on compression of free standing gels twice in succession and is capable of providing both fundamental and empirical data on the mechanical properties of gels. It has the advantage of providing data at both low and high strains allowing gels to be characterised by multiple parameters. These include: · modulus: a measure of gel firmness when lightly squeezed · hardness: a measure of the force required to rupture the gel · brittleness: a measure of how far the gel can be squeezed before it ruptures; it is important to note that the higher the brittleness value the less brittle the gel is, i.e., it has to be compressed further to break · elasticity: a measure of how far the gel springs back after the first compression cycle · cohesiveness: indicates the degree of difficulty in breaking down the gel in the mouth. Texture profile analysis has been used to characterise a diversity of foods and

212


Fig. 9.3

Schematic comparison of the gel texture of HA and LA gellan gum with other common gelling agents.

hydrocolloid gels. A more detailed account of the technique can be found in a review by Pons and Fiszman.16 HA and LA gellan gum gels have very different textures that can be considered to be at opposite ends of the textural spectrum of hydrocolloid gels and Fig. 9.3 shows schematically how gellan gum gels compare with other

Fig. 9.4

Texture profile of HA (ÐÐ) and LA (-----) gellan gum gels measured on 1% gels at 70% strain.

Gellan gum

213

Fig. 9.5 Effect of HA and LA gellan gum blend ratio on the modulus and brittleness of gels prepared at 0.5% total gum concentration.

common gelling systems. LA gellan gum forms hard, non-elastic, brittle gels whereas HA gellan gum gels are soft, elastic and non-brittle. A comparison of the texture of HA and LA gellan gum gels, made using texture profile analysis, is shown in Fig. 9.4. It is immediately apparent that through blending of the two forms, a diverse range of textures can be achieved that encompass many of the textures produced by other hydrocolloids (Fig. 9.5). It has been demonstrated by differential scanning calorimetry (DSC), and rheological measurements that mixtures of the HA and LA forms exhibit two separate conformational transitions at temperatures coincident with the individual components.8,13 This is important to note since in mixtures consideration for the high setting temperature of the HA gellan gum will need to be made. No evidence for the formation of double helices involving both HA and LA molecules has been found.17 Properties of the blended system can be varied through control of the blend ratio and level of ions in the mixture.18,19 At low ionic concentrations the HA form predominates, but as the ionic concentration increases the contribution of the LA form to the texture increases.

9.5

Uses and applications

Before discussing the main applications of gellan gum, an overview of the key properties of both the HA and LA forms is given in Table 9.6. This provides a useful frame of reference from which existing applications can be understood and new opportunities visualised.

214


Table 9.6

Comparison of the key properties of HA and LA gellan gum

Hydration Sequestrants Viscosity Gelling ions Setting temperature Melting Clarity Texture

Low acyl gellan gum

High acyl gellan gum

> 80 ëC Yes Low Yes (mono or divalent or acid) 25±60 ëC No (except low ionic strength and in milk) Clear Firm, brittle

> 70 ëC No High Not required 70±80 ëC Yes Opaque Soft, elastic

9.5.1 Dessert jellies Water-based dessert jellies are popular throughout the world and have a range of textures. The firm brittle texture of LA gellan gum, for example, complements the flavour of fruit juice jellies. Alternatively, combinations of HA and LA gellan gum can be used to produce jellies with a variety of textures. Products can be `ready-to-eat' (RTE) or in dry mix form. Example formulations are provided below. Formulation 9.1 is an example of a fruit juice jelly prepared with LA gellan gum. It can be made with apple, orange, grape, pineapple or grapefruit juice and will hydrate as a dry mix in a water hardness of up to 600 ppm (as CaCO3). The pH and solids vary according to the juice used, but are typically pH 3.5±3.7 and 17% total soluble solids. Alternatively, blends of LA and HA gellan gum can be used to give a range of textures. Blend ratio and gum concentration will depend on the final texture required but a 3:1 HA:LA gellan gum blend at approximately 0.3% is recommended as a starting point for textural evaluation. Formulation 9.1

Recipe for fruit juice jelly using LA gellan gum

Ingredients Water Fruit juice Sugar Citric acid anhydrous Tri sodium citrate dihydrate LA gellan gum

Weight (g)

(%)

250.0 250.0 90.0 2.4 1.8 0.9

42.00 42.00 15.15 0.40 0.30 0.15

Preparation 1. Pre-blend all the dry ingredients. 2. Heat the water to boiling and dissolve the dry ingredients in the hot water. 3. Add the fruit juice, mix and chill. The gel sets at approximately 40±45 ëC and the use of chilled fruit juice with dry-mix desserts ensures a rapid set.

Gellan gum Formulation 9.2

215

Recipe for a dessert jelly using LA gellan gum and gelatin

Ingredients

Weight (g)

(%)

Water Sugar Gelatin (type B, 240 Bloom) Citric acid anhydrous Tri sodium citrate dihydrate LA gellan gum Colour and flavour

500.0 90.0 10.2 2.3 1.6 0.35 as required

82.6 15.0 1.7 0.38 0.26 0.06

Preparation 1. Blend all the dry ingredients. 2. Heat the water to boiling and dissolve blend into the hot water by stirring for 1±2 minutes. 3. Deposit and chill.

LA gellan gum can also be used to modify the properties of traditional gelatin dessert jellies and an example is given in Formulation 9.2. The LA gellan gum in this formulation raises the initial set temperature of the dessert to around 35 ëC, allowing more rapid processing of an RTE product. The formulation can also be used in dry mix composite desserts allowing further layers to be added more quickly than with gelatin alone. The time to consumption is, however, not reduced as the maturation time of the gelatin gel remains unchanged. The gellan gum also raises the melting point of the gel so that desserts maintain their shape for longer, when removed from the fridge. This approach can also be used in savory gelled products such as aspics. Gellan gum is an anionic polysaccharide (ÿve charge) whereas gelatin is a protein and as such its overall charge will be dependent on the pH of the system. Below its isoelectric point the gelatin will carry an overall positive charge and will therefore interact with the negatively charged polysaccharide. This can lead to cloudiness in the gel or even precipitation. For this reason it is recommended to use type B gelatins since these have the lowest isoelectic point (pH 4.5±5.5). The extent of the interaction will depend on the pH and the ratio of gelatin to gellan gum. 9.5.2 Suspending agent Gellan gum is commonly used as a gelling agent; however, it can be used to prepare structured liquids which are extremely efficient suspending agents. These structured liquids are gelling systems which have been subjected to shear either during or after the gelation process. The application of shear disrupts normal gelation and results, under certain conditions, in smooth homogeneous, pourable systems often referred to as `fluid gels'.20 To produce smooth homogeneous fluid gels with gellan gum, systems must be formulated to give weak gelation, either by manipulating the ion type and concentration or gellan gum concentration. The viscosity and structure of the

216


system correlates with the gel strength of the unsheared gel. Therefore, the greater the gel strength of the unsheared gel, the greater the viscosity and structure will be when the system is sheared. Systems which gel too strongly, however, can give rise to a grainy appearance in the final fluid. Gellan gum fluid gels can be prepared using a variety of processes. Three potential processes are outlined schematically in Fig. 9.6. The first step in each case is to hydrate the gellan gum through a combination of heat and sequestrants. Method 1 simply involves continually stirring the solution as it cools to form the fluid gel or allowing the weak gel to form undisturbed, then shearing to form the fluid gel. Alternatively, in method 2 the hot gellan gum solution can be added to cold water whilst mixing. This results in cooling of the solution and formation of a fluid gel. In method 3 it is possible to prepare gellan gum solutions that will not gel on cooling. Addition of ions to these cold solutions results in gelation and formation of a fluid gel. The application of shear can be achieved by using stirring, homogenisation, filling or even `shake before use'. Shear can also be applied during or after gelation. UHT, HTST and processes involving scraped surface heat exchangers (i.e. for the production of custards, gravies and ketchup) are an ideal way to shear during gelation as the solution cools. Gellan gum fluid gels can be used to produce shelf stable suspensions in a variety of beverage products.21 Generally, HA gellan gum should be used at approximately 0.02±0.05% to give a smooth fluid gel. For LA gellan gum the use level is dependent on the ionic concentration in the system and a guide to the formulation of fluid gels using LA gellan gum is given in Table 9.7. Example formulations for beverages

Fig. 9.6

Outline of potential processes for the preparation of gellan gum fluid gels.

Gellan gum Table 9.7

217

Guidelines for formulation of LA gellan gum fluid gels

Ion

Concentration

Calcuim

Low (< 50ppm) Optimum (100±600ppm) High (> 600ppm) Low (< 0.25%) Optimum (0.5±2.0%) High (4.0±10%)

Sodium Milk Sugars

LA gellan gum concentration (%) 0.05±0.2 0.03±0.05 0.05±0.2 0.05±0.2 0.03±0.05 0.05±0.2 0.05±0.2 0.1±0.3

(40±60%)

using LA or HA gellan gum which can be used to suspend gelled beads or fruit pulp are given below. Formulation 9.3 provides a starting point for a beverage type fluid gel. It has a pH of 2.9 and a setting temperature of approximately 15 ëC. It can be used to suspend jelly beads and is prepared as outlined in method 1 of Fig. 9.6 by shearing after the weak gel has been allowed to form. Formulation 9.4 is an example of a fluid gel formed with HA gellan gum. HA gellan gum fluid gels are less sensitive to the ionic conditions and have longer, more elastic flow properties when compared to LA gellan gum fluid gels.

Formulation 9.3

Recipe for a fluid gel for beverages using LA gellan gum

Ingredients Part 1 Sucrose Tri sodium citrate dihydrate LA gellan gum Sodium benzoate Deionised water Part 2 Citric acid Calcium lactate Deionised water

Weight (g)

(%)

112.0 0.60 0.28 0.20 862.0

11.25 0.06 0.028 0.02 86.60

5.00 0.25 15.00

0.50 0.025 1.517

Preparation 1. Blend the sucrose, tri sodium citrate dihydrate, LA gellan gum and sodium benzoate and disperse in the deionised water of Part 1. 2. Heat the dispersion to 70±80 ëC to hydrate. 3. Dissolve the citric acid and calcium lactate in the deionised water of Part 2 and add to the hot gum solution. 4. Cool the sample to below 15 ëC undisturbed. 5. Gently agitate the sample to form a fluid gel.

218


Formulation 9.4

Recipe for a pulp suspension beverage using HA gellan gum

Ingredients Water Fruit juice Sugar HA gellan gum Tri sodium citrate dihydrate Citric acid anhydrous Potassium citrate

Weight (g)

(%)

338.10 100.0 60.0 0.25 0.25 0.9 0.5

67.62 20.0 12.0 0.05 0.05 0.18 0.1

Preparation 1. Blend the HA gellan gum with the tri sodium citrate dihydrate and disperse in the water. 2. Heat the dispersion to 90 ëC to hydrate the gum. 3. At 90 ëC add the remaining dry ingredients and the fruit juice. 4. Cool to room temperature whilst mixing to form the fluid gel.

9.5.3 Dairy Unlike water systems, much of the calcium in milk is associated with the milk proteins. During heating any remaining free calcium is also bound by the proteins and therefore does not interfere with the hydration of the gellan gum. Because of this, both HA and LA gellan gum will hydrate in milk above approximately 80 ëC without the need for a sequestrant. Milk also contains sodium and potassium ions and it is therefore not usually necessary to add additional gelling ions to milk systems. Because the LA gellan gum is gelled with a low level of monovalent ions (predominantly K+), milk gels are thermally reversible, melting at approximately 95 ëC. Thermal stability of LA gellan gum milk gels can be improved by the addition of calcium. Care must be taken when adding calcium to hot milk since it can result in precipitation of the milk proteins if added above 70 ëC. It is recommended to cool the gellan/milk mixture to between 55 and 65 ëC before adding the calcium. This temperature range is above the gelation temperature of the LA gellan gum but below the temperature at which milk protein precipitation occurs. In many dairy systems milk powders are used. These powders are natural sequesterants and will bind calcium from the water used for reconstitution. Therefore, it is not usually necessary to add a sequestrant when water of hardness up to 400 ppm (as CaCO3) is used for reconstitution. Some sequestrant may be required if less than 2% milk powder is being used or harder water is used to reconstitute the milk powder. Milk beverages As described in Section 9.5.2, HA gellan gum at low concentrations is able to form a very weak gel network often referred to as a fluid gel. These fluid gels have extremely good suspension properties and can be used in a range of neutral dairy and soya based products such as chocolate milk. Development of this application was initially limited due to creation of off-flavours as a result of

Gellan gum

219

residual enzyme activity in the native, HA gellan gum acting on the milk. The off-flavour, which is reminiscent of cleaning chemicals, renders the product unpalatable and is linked to the development of para-cresol. Development of a process in which the HA gellan gum is pre-treated with a denaturing agent that is thought to act on the residual enzymes in the gellan gum has led to a new grade of gellan gum for this application.22 KELCOGELÕ HM-B is a standardised product containing the pre-treated HA gellan gum and can be used at 0.1±0.12% for stabilisation of cocoa in chocolate milk. The HA gellan gum is tolerant to a wide range of UHT conditions and products can be filled at higher temperatures than with carrageenan, the traditional hydrocolloid for this application. It provides excellent suspension of cocoa and long-term stability. It is functional in reconstituted milk, fresh milk, whey substituted beverages and low protein milk beverages. Yogurt The standard yogurt process can be followed when using LA gellan gum for both set and stirred yogurt. There are various ways in which yogurt containing LA gellan gum can be made depending on the usual manufacturing process and on the desired properties of the final yogurt. In all cases the initial steps are the same: the LA gellan gum should be blended with skimmed milk powder and other stabilisers (if required) and dispersed in cold milk before heating, homogenising and pasteurising. Generally, the fermentation time is not affected by the presence of LA gellan gum. The important factor to remember is that the setting temperature of LA gellan gum in skimmed milk is about 41 ëC. If shear is applied through the setting temperature a fluid gel will be formed. This acts like a gel under static conditions, but flows like a liquid when shear is applied. If, however, shear is applied below the setting temperature in yogurt systems, a broken gel may result which can lead to unsatisfactory lumps in the final product. Typical use levels for LA gellan gum in yogurt are 0.04%. It can be used in combination with other stabilisers such as starch depending on the final texture required. 9.5.4 Sugar confectionery One of the fundamental techniques for the manipulation of the texture of sugar confectionery is to use combinations of a variety of sugars such as sucrose, glucose, fructose and various corn syrups. Combinations of sugars produce desirable textures, as well as preventing crystallisation of individual sugars. Another critical ingredient is the hydrocolloid. These impart structure to the product and provide the characteristic jelly texture. Before describing how to make confectionery jellies with gellan gum, it is worth discussing the influence of sugars on the properties of gellan gum. Effect of sugars on LA gellan gum The presence of sugars has two major effects on the properties of LA gellan gum gels. Firstly, the ion requirements for optimum gel properties are reduced. The

220


Fig. 9.7

Effect of sucrose concentration on the modulus ( ), hardness (ú) and brittleness (n) of 0.5% LA gellan gum gels.

presence of 40% w/w sugar approximately halves the calcium required for maximum gel modulus, from 8±10 mM in water gels to 4±5 mM in the sugar gels. Addition of 60% w/w sugar results in an approximately ten-fold reduction in the requirement for calcium, with only 0.5±1.0 mM added calcium required for maximum gel modulus. Similar reduction in the requirements for sodium and potassium are also seen (Fig. 9.2). Secondly above approximately 40% sugar gels become less firm and less brittle, i.e., softer and more elastic (Fig. 9.7). These effects are believed to be the result of the sugars inhibiting the aggregation step of the gelation process.23,24 These effects are also influenced by the type of sugar. Sucrose has a greater inhibitory effect than glucose, fructose or corn syrups (Table 9.8).25 The differences observed between sugars mean that texture can, to some degree, be varied by manipulating the sugar composition of the system. For example, partial replacement of sucrose with fructose or corn syrup, a common practice to control crystalisation in confectionery manufacture, results in firmer, more brittle gels.26 Effect of sugars on HA gellan gum Less is known about the specific effects of sugars on HA gellan gum. However, addition of sugars to HA gellan gum gels generally results in an increase in the force required to break the gel. Setting and melting temperature also increase with increasing sugar concentration. In the presence of high levels of sugar (70±

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221

Table 9.8 Effect of sugars at 40% and 60% w/w on the textural properties of 0.5% w/w LA gellan gum gels prepared at ion concentrations giving maximum gel modulus Sugar

Fructose Glucose Sucrose Maltose 42DE corn syrup 14DE maltodextrin

Modulus (Ncmÿ2)

Brittleness (%)

40% w/w

60% w/w

40% w/w

60% w/w

14.1 12.9 13.5 15.5 19.0 16.1

3.70 2.17 1.60 3.83 5.06 5.88

31.3 36.7 30.2 30.7 27.9 24.1

53.6 62.9 63.3 51.4 53.0 43.1

80%), HA gellan gum has very high viscosity even when hot. This can make processes such as mixing and depositing difficult. This is often compounded by the high setting temperature which can result in pre-gelation, i.e., gel formation prior to deposition of the confectionery mix. However, incorporation of low levels of HA gellan gum into confections made with LA gellan gum will increase the chewiness of the jellies. Preparation of confectionery jellies LA gellan gum may be used alone or in combination with other gelling agents to produce jelly confectionery by traditional processes. Examples are provided in Formulations 9.5 and 9.6. When prepared with LA gellan gum as the sole gelling agent (Formulation 9.5), the jellies are firm with a short, clean bite and flavour. The jellies can be removed from the starch moulds after about 2 h but are usually stoved for up to 72 h before demoulding. Addition of a thin boiling starch as outlined in Formulation 9.6 results in a chewier texture. Combinations of LA gellan gum with carrageenan can be used to produce gelatin-free confectionery which is suitable for halal. Pre-gelation is the premature gelation of the confectionery mix prior to, or during, depositing. This makes depositing difficult and results in a weaker gel structure and grainy texture. Table 9.9 provides a guide to preventing pregelation in gellan gum confections. 9.5.5 Fruit preparations This application covers a wide variety of systems from 30 to 75% total soluble solids. Much of the understanding of the effects of sugars described in confectionery applications can be applied to these systems. In addition, the type of fruit used in the formulation is a key consideration when using LA gellan gum since the ion content and pH will vary. Fruit composition may also vary during the season. Table 9.10 shows that the ionic composition varies considerably between different fruits with most fruits containing significant levels of potassium ions.27 These ionic concentrations become increasingly significant in

222


Formulation 9.5

Recipe for jelly sweets using LA gellan gum

Ingredients

Weight (g)

(%)

Sucrose Glucose syrup (42DE) Water Citric acid anhydrous Tri sodium citrate dihydrate KELCOGELÕ F gellan gum Calcium hydrogen orthophosphate Flavour and colour

159.0 159.0 120.0 5.00 5.00 3.75 0.20 as required

35.20 35.20 26.51 1.11 1.11 0.83 0.04

Preparation 1. Blend the LA gellan gum and calcium hydrogen orthophosphate with 1.0 g of tri sodium citrate dihydrate and 40 g of sucrose and disperse in the water. 2. Heat to boiling to hydrate the gellan gum then add the remainder of the sugar while continuing to boil. 3. Add pre-warmed glucose syrup while maintaining the temperature above 90 ëC. 4. Cook the liquor to 80±82% total solids then cool to 90 ëC. 5. Dissolve the citric acid and remainder of the tri sodium citrate dihydrate, colour and flavour in 20 cm3 of water and stir into the liquor. 6. Deposit at 76±78% total solids into starch moulds. 7. Stove to final solids as required.

Formulation 9.6 Recipe for jelly sweets using LA gellan gum and thin boiling starch Ingredients

Weight (g)

(%)

Water Glucose syrup (42DE) Sugar Thin boiling starch (FLOGEL 60) LA gellan gum Tri sodium citrate dihydrate Citric acid anhydrous Calcium hydrogen orthophosphate Flavour and colour

220.0 159.0 148.5 18.8 3.5 1.8 1.8 0.2 as required

39.0 28.2 28.1 3.4 0.62 0.32 0.32 0.04

Preparation 1. Slurry the starch in 50 g of water. 2. Blend the LA gellan gum, calcium hydrogen orthophosphate and tri sodium citrate dihydrate with 40 g of sugar and disperse in the remainder of the water. 3. Heat the dispersion to boiling to hydrate the gellan gum then add the remaining sugar and continue to boil. 4. Add pre-warmed glucose syrup and cook to boiling. 5. Add the starch slurry, breaking the boiling point and continue to cook to 78% total solids. 6. Add colour, flavour and citric acid pre-dissolved in a small amount of water. 7. Deposit into starch moulds at 74% total solids and stove to final solids as required.

Gellan gum Table 9.9

223

A guide to the prevention of pre-gelation in confectionery mixes

Problem

Possible causes

Solution

Pre-gelation when acid added

Hard water

Add sodium hexameta phosphate

Depositing soluble solids too high

Lower depositing solids

pH too low

Add sodium citrate with citric acid

Hard water

Increase sequestrant level

Soluble solids too high

Add water to lower soluble solids

Pre-gelation before acid added

Table 9.10 Fruit Apple Blackcurrant Raspberry Strawberry Apricot Peach

Ionic composition of raw fruits27 Ca++ (mg/100g)

Mg++ (mg/100g)

Na+ (mg/100g)

K+ (mg/100g)

4 60 25 16 15 7

3 17 19 10 11 9

2 3 3 6 2 1

88 370 170 160 270 160

medium to high solids systems where gellan gum ion requirements are greatly reduced. Therefore, formulations optimised for one fruit will often need modification to accommodate different fruits. Formulation 9.7 is an example of a low solids (36%) jam which can be formulated to give a range of textures. HA gellan gum provides a soft, spreadable jam with excellent sheen. The addition of a proportion of LA gellan gum may be used where a firmer textured jam is required. LA gellan gum alone can be used to give a more bake stable jam. Various fruits can be used, including strawberries, raspberries and blackcurrants. Formulation 9.8 is slightly higher in solids than Formulation 9.7 and produces a lightly gelled yogfruit with evenly suspended fruit pieces. The gelled structure can be broken down by pumping to give a smooth, viscous yogfruit (pH 3.9, soluble solids 40%). Finally, Formulation 9.9 with 55% fruit and no added water demonstrates the properties of a gellan gum and starch-based preparation. The LA gellan gum filling has a glossy appearance, good flavour release and excellent bake stability (pH 3.4, tss 56%).

224


Formulation 9.7

Recipe for a reduced sugar jam using HA or LA gellan gum blend

Ingredients Frozen strawberries Sugar Water Gellan gum* Tri sodium citrate dihydrate Potassium sorbate Citric acid solution (50% w/w)

Weight (g)

(%)

450.0 283.5 260.0 2.5 0.5 1.0 2.5

45.0 28.35 26.0 0.25 0.05 0.10 0.25

* High acyl and/or low acyl gellan gum can be used depending on desired final texture.

Preparation 1. Dry blend the gellan gum, tri sodium citrate dihydrate and potassium sorbate with the sugar and disperse into the water. 2. Add the fruit and heat to boiling. Cook for 1±2 minutes to ensure hydration of the gellan gum. Check the soluble solids. 3. Remove from the heat and add the citric acid solution. Fill into jars and cap immediately. Formulation 9.8

Recipe for a peach yogfruit using LA gellan gum

Ingredients Peach pureÂe Diced peach Glucose syrup LA gellan gum Tri sodium citrate dihydrate Sodium benzoate

Weight (g)

(%)

200.0 200.0 300.0 0.35 1.80 0.25

28.50 28.50 42.65 0.05 0.26 0.04

Preparation 1. Combine the fruit and glucose syrup. 2. Add the tri sodium citrate dihydrate, LA gellan gum and sodium benzoate and heat to 90 ëC with constant stirring. 3. Hold for 1 minute then cool, with stirring, to 60 ëC. 4. Deposit and allow to cool undisturbed. Note: The tri sodium citrate dihydrate in the formulation is added to give a final pH of 3.9. The addition level may be varied depending on the fruit used, and the final pH required.

9.5.6 Other applications Gellan gum forms films and coatings that can be used in breadings and batters. Films offer several advantages, particularly their ability to reduce oil absorption by providing an effective barrier. Films can be prepared by applying a hot solution of gellan gum on to the surface of the food product, by spraying or dipping, and allowing to cool. Alternatively, in the case of LA gellan gum, the food can be dipped into a cold solution of the gum, allowing ions to diffuse into

Gellan gum Formulation 9.9

225

Recipe for a bake-stable fruit preparation using LA gellan gum

Ingredients Apple (thawed) Sucrose Modified starch (THERMFLO) LA gellan gum Citric acid solution (50% w/w) Tri sodium citrate dihydrate

Weight (g)

(%)

210.0 160.8 8.00 0.32 0.80 0.88

55.2 42.2 2.10 0.12 0.20 0.18

Preparation 1. Pre-blend the dry ingredients, add to the apple and heat with stirring to boiling. 2. Remove from heat, add the citric acid solution, mix well and deposit. 3. Leave to gel before use. Shear, and use as required.

the solution, resulting in gelation or film formation. LA gellan gum can also be used to produce fat free adhesion systems. Spraying of a cold solution of LA gellan gum onto the surface of products such as nuts, crisps and pretzels forms an instant thin layer of gel when it reacts with the salt thus facilitating adhesion of spice, flavour or sweetener blends.

9.6 Regulatory status In Japan, gellan gum has been considered a `natural' food additive since 1988. It is now approved for food use in the USA and the European Union as well as Canada, South Africa, Australia, most of South East Asia and Latin America. Gellan gum appears as E418 in the European Community Directive EC/95/2 in Annex 1. Both the Joint FAO/WHO Expert Committee on Food Additives (JECFA) and the European Community Scientific Committee for Food has given gellan gum an Acceptable Daily Intake (ADI) of `not specified'. Combinations of HA and LA gellan gum have one name. A manufacturer may label a product made with a combination of both types of gellan gum simply, È418' or `gellan gum'.

9.7

Future trends

The current commercial HA and LA gellan gum products can be considered as being at opposing ends of the textural spectrum available with hydrocolloid gelling agents (Fig. 9.3). Blends of the two types enable some intermediate textures to be created but the mixed system retains the high setting temperature of the HA product and the ion sensitivity of the LA product. Far more interesting are gellan gums of intermediate acyl content as these show much more variation in texture and a single homogeneous setting behaviour.28,29 Methods for creating these partially acetylated products exist but they are yet to be produced on a commercial scale.30 Realisation of this control over the degree of acylation of gellan gum could lead to a truly universal gelling agent.

226


9.8

Sources of further information and advice

www.CPKelco.com Imeson, A. (1999) Thickening and Gelling Agents for Food, 2nd edn. Aspen Publishers Inc., Gaithersburg, MD.

9.9 1. 2. 3. 4. 5. 6. 7.

8. 9. 10. 11.

References and MORRIS, V.J. (1983) `Structure of the acidic extracellular gelling polysaccharide produced by Pseudomonas elodea', Carbohydr. Res., 124, 123±33. JANSON, P.-E., LINDBURG, B. and SANDFORD, P.A. (1983) `Structural studies of gellan gum, an extracellular polysaccharide elaborated by Pseudomonas elodea', Carbohydr. Res., 124, 135±9. KUO, M.-S., MORT, A.J. and DELL, A. (1986) Ìdentification and location of L-glycerate, an unusual acyl substituent in gellan gum', Carbohydr. Res., 156, 173±87. CHANDRASEKARAN, R., MILLANE, R.P., ARNOTT, S. and ATKINS, E.D.T. (1988) `The crystal structure of gellan', Carbohydr. Res., 175, 1±15. CHANDRASEKARAN, R., PUIGJANER, L.C., JOYCE, K.L. and ARNOTT, S. (1988) `Cation interactions in gellan: an X-ray study of the potassium salt', Carbohydr. Res., 181, 23±40. CHANDRASEKARAN, R. and THIALAMBAL, V.G. (1990) `The influence of calcium ions, acetate and L-glycerate groups on the gellan double helix', Carbohydr. Polym., 12, 431±442. CHANDRASEKARAN, R., LEE, E.J., RADHA, A. and THAILAMBAL, V.G. (1992) `Correlation of molecular architectures with physical properties of gellan related polymers', in Frontiers in Carbohydrate Research ± 2, ed. R. Chandrasekaran. Elsivier Applied Science, New York, pp. 65±84. MORRIS, E.R., GOTHARD, M.G.E., HEMBER, M.W.N., MANNING, C.D. and ROBINSON, G. (1996) `Conformational and rheological transitions of welan, rhamsan and acylated gellan' Carbohydr. Polym., 30, 165±75. MORRIS, E.R., REES, D.A. and ROBINSON, G. (1980) `Cation-specific aggregation of carrageenan helices: domain model of polymer gel structure', J. Mol. Biol., 138, 349. GRAZDALEN, H. and SMIDSRéD, O. (1987) `Gelation of gellan gum', Carbohydr. Polym., 7, 371±93. O'NEILL, M.A., SELVENDRAN, R.R.

NODA. S., FUNAMI, T., NAKAUMA, M., ASAI, I., TAKAHASHI, R., AL-ASSAF, A., IKEDA, S.,

and PHILLIPS, G.O. (2008) `Molecular structures of gellan gum imaged with atomic force microscopy in relation to the rheological behaviour in aqueous systems. 1. Gellan gum with various acyl contents in the presence and absence of potassium', Food Hydrocolloids, 22, 1148±59. SANDERSON, G.R. and CLARK, R.C. (1984) `Gellan gum, a new gelling polysaccharide', in Gums and Stabilisers for the Food Industry 2, eds. G.O. Phillips, D.J. Wedlock, and P.A. Williams. Pergamon Press, Oxford, pp. 201±10. NISHINARI, K.

12. 13.

KASAPIS, S., GIANNOULI, P., HEMBER, M.W.N., EVAGELIOU, V., POULARD, C., TORT-

and SWORN, G. (1999) `Structural aspects and phase behaviour in deacylated and high acyl gellan systems', Carbohydr. Polym., 38 145±54.

BOURGEOIS, B.

Gellan gum 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28.

29. 30.

227

and SWANSON, B.G. (2004) `Gelling temperatures of high acyl gellan as affected by monovalent and divalent cations with dynamic rheological analysis', Carbohydr. Polym., 56 27±33. BOURNE, M.C. (1978) `Texture profile analysis', Food Technology, 32, 67±72. PONS, M. and FISZMAN, S.M. (1996) Ìnstrumental texture profile analysis with particular reference to gelled systems', Journal of Texture Studies, 27, 597±624. MATSUKAWA, S. and WATANABE, T. (2007) `Gelation mechanism and network structure of mixed solution of low- and high-acyl gellan studied by dynamic viscoelasticity, CD and NMR measurements', Food Hydrocolloids, 21, 1355±61. MAO, R., TANG, J. and SWANSON, B.G. (2000) `Texture properties of high and low acyl mixed gellan gels', Carbohydr. Polym., 41, 331±8. HUANG, Y., TANG, J., SWANSON, B.G. and RASCO, B.A. (2003) Èffect of calcium concentration on the textural properties of high and low acyl mixed gellan gels', Carbohydr. Polym., 54, 516±22. SWORN, G., SANDERSON, G.R. and GIBSON, W. (1995) `Gellan gum fluid gels' Food Hydrocolloids, 9, 265±71. VALLI, R. and JACKSON, P.H. (2004) `Shelf stable suspensions: gellan gum blend forms fluid gels in beverages', Food and Beverage Asia, April, pp. 54±57. VALLI, R.C. and MORRISON, N.A. (2002) `Methods of making sterilized milk compositions comprising native gellan gum'. Patent No. PCT/WO 02/060268 A2. SWORN, G. (1996) `Gelation of gellan gum in confectionery systems' in Gums and Stabilisers for the Food Industry 8, eds. G.O. Phillips, P.A. Williams and D.J. Wedlock. IRL Press, Oxford, pp. 341±9. SWORN, G. and KASAPIS, S. (1998) `The use of Arrhenius and WLF kinetics to rationalise the mechanical spectrum in high sugar gellan systems', Carbohydr. Res. 309, 353±61. SWORN, G. and KASAPIS, S. (1998) Èffect of conformation and molecular weight of co-solute on the mechanical properties of gellan gum gels', Food Hydrocolloids, 12, 283±90. GIBSON, W. (1992) `Gellan gum', in Thickening and Gelling Agents for Food, ed. A. Imeson. Blackie Academic and Professional, Glasgow, pp. 227±49. MCCANCE and WIDDOWSON'S The Composition of Foods, 5th Edition, RSC and MAFF, 1991. BAIRD, J.K., TALASHEK, T.A. and CHANG, H. (1992) `Gellan gum: Effect of composition on gel properties', in Gums and Stabilisers for the Food Industry 6, eds. G.O. Phillips, P.A. Williams and D.J. Wedlock. IRL Press, Oxford, pp. 479± 87. MORRISON, N.A., SWORN, G. CLARK, R.C., TALASHEK, T. and CHEN, Y-L. (2002) `New textures with high acyl gellan gum', in Gums and Stabilizers for the Food Industry 11, eds. G.O. Phillips and P.A. Williams. IRL Press, Oxford, pp. 297±305. SWORN, G., CHEN, Y-L., MORRISON, N.A., TALASHEK, T. and CLARK, R. (1999) `Modified gellan gum composition process for preparation of same and use thereof'. Patent No. PCT/WO 99/64468. HUANG, Y., SINGH, P., TANG, J.

10 Galactomannans W. C. Wielinga, retired in 2000 from Meyhall AG, Kreuzlingen, Switzerland, which was subsequently acquired by Danisco A/S

Abstract: The introduction provides information about the worldwide availability of important seed gums. The following section describes the raw materials and structure of seed galactomannans, including description of the composition of the seeds of the carob tree, tara shrubs and the guar plant, and the amount of recoverable endosperm in fenugreek seeds. For the four types of gum discussed, the amount of overall galactose content is indicated, and the fine structure of the different galactomannans is briefly described, as far as information is available. There is also brief discussion of a possible biosynthesis route for galactomannans, derived from the literature. Attention is also drawn to EC and FAO/WHO specifications for the molecular weights of carob bean gum (E410) and guar gum (E412). The manufacture of carob bean gum/tara gum and guar gum is described and a manufacturing abstract for fenugreek gum is derived from two recent patents. Brief reference is also made to the development of novel technologies for the purification of guar endosperm. The various galactomannan gums are characterized in the usual way. The relationship of molecular weights of galactomannans of straight and depolymerized carob bean gum and guar gum and the usual Brookfield viscosities are determined. This kind of viscosity is examined in relation to the concentration of aqueous solutions, using regression equations. Uses and applications of galactomannans are very briefly discussed and attention is drawn to other publications in this respect. Potential future developments are also briefly examined. Key words: water soluble seed gums, carob bean gum, tara gum, guar gum, fenugreek gum, E-numbers, availability, production, galactose-mannose ratios, properties, depolymerized gums, application.

Galactomannans 229

10.1

Introduction

Galactomannans are multifunctional macromolecular carbohydrates found in various albuminous or endospermic seeds. The seed galactomannans from the carob tree (Ceratonia siliqua L.) and from the guar plant (Cyamopsis tetragonoloba L.) are widely used, while the kernels from the tara shrub (Cesalpinia spinosa L.) are used to a much lesser extent. The fenugreek plant (Trigonella foenum graecum L.) is another legume that supplies a further kind of galactomannans. Ground endosperms are the source of trade galactomannan gums. The recovered endosperm halves, of the required purity, of carob, tara and guar, and the endosperm parts of fenugreek seeds, are ground to obtain a fine off-white powder. World production of carob pods is estimated at about 300,000±350,000 t/ year, yields depending on cultivar, region and farming practice. The carob pod is called St. John's bread and has two main constituents: · 90 wt% of pulp, containing a high amount of sugars (48±56 wt%) with low molecular weight · 10 wt% of seeds or kernels (undigestible). The carob kernels are composed of 30±35 wt% of hull, 20±25 wt% of germ and 40±45 wt% of endosperm on an absolute dry basis. The annual consumption of carob bean gum in the food industry is 9,000±10,000 t. The approximate composition of tara seeds is: ca. 38 wt% of hull, ca. 40 wt% of germ and ca. 22 wt% of endosperm on an absolute dry basis. About 1,500± 2,000 t of tara gum per year are available to the food industry. The average total quantity of guar seeds worldwide is estimated at about 500,000 tons p.a. However, large fluctuations of annual availability of seeds occur, mainly due to weather conditions. The seeds are composed of 20±22 wt% of hull, 44±46 wt% of germ and 32±36 wt% of endosperm on an absolute dry basis. The annual consumption of guar gum in the food industry is about 55,000 t. For fenugreek, the annual worldwide seed volume is approximately 30,000± 50,000 t, mainly used for spice production. This volume could easily be increased on demand (see `Fenugreek has a role in south-eastern Australian farming systems' by Kate McCormick et al. ([email protected]). Fenugreek seeds yield about 25 wt% of gum. For ease of comparison, Table 10.1 illustrates the annual consumption in 1990 of different food additives in grams per year per capita in various countries.

10.2

Raw materials and structure

These polysaccharides are strongly hydrophilic, enabling the endosperm to imbibe water to protect the embryo against subsequent drought, during and before germination. They become metabolized after germination.1 During

230


Table 10.1 Annual consumption of certain hydrocolloids per capita in grams per year for 1990 (for US citizens and for those in Germany, France, UK and Italy (D, F, GB, I)) Hydrocolloids

US

D, F, GB, I

Starch products Gelatin Agar Agar Alginates Carrageenans Guar gum Arabic gum Carob bean gum CMC Other cellulose derivatives Xanthan gum Pectin

1300 65 2 10 11 34 22 8 23 6 13 11

1281 122 3 10 18 39 59 18 6 1 3 19

Total

1505

1576

germination the endosperm absorbs up to 75 wt% of water, based on the dry weight of the seed. This allows the diffusion of enzymes required for the germination process and enables the transport of metabolic low molecular weight end-products, needed for the growth of the plant. The carob tree bears pods with an average yield of 50±70 kg, which can be collected from orchards with minimum management, producing 2,000±3,000 kg/ ha. In irrigated orchards an average of 250±300 kg of pods per tree is possible, yielding 12,300 kg of pods/ha. The kernels are released in a process called kibbling. The pods are broken between two rollers with special geometry, and the freed seeds are then separated from the rest of the pods using special screens. Due to its high sugar content, the pod pulp is a staple in the diet of farm animals. It is also used to produce alcohol and is sold in fine powder form as a cacao substitute. People ate carob pods in times of famine and children still like them as snacks. The main interest, however, lies in the kernels. The kernel is oval or oblong in shape, 8±10 mm long, 7±8 mm wide and 3±5 mm thick. The glossy brown testa is hard and smooth. A kernel weighs ca. 0.2 g with small deviations and was used as a weight unit for gold and precious stones (carat is derived from the Latin word ceratonia). The endosperm of Ceratonia siliqua seeds or kernels consists of living cells, which can synthesize the enzymes to hydrolyse the galactomannans (galactosidase, EC.3.2.1.22, endo- -mannanase, EC.3.2.1.78 and -mannosidase, EC.3.2.1.25). The guar plant is bush-like with a height of 57±105 cm, depending on the variety. It is very drought resistant. Once it has germinated, it requires very little surface water during the main growth period, i.e. for 20±25 weeks. To induce maturation of the seeds, water is needed again. The monsoon season of the

Galactomannans 231 Indian continent, especially in the north-western part of India and north-eastern part of Pakistan usually provides the right amount of rainfall at the right time of year for optimal growth. The growing season starts in July or August in India and Pakistan and the harvest takes place in November or December. The guar pod is 5±8 cm long, almost round in shape and ca. 1 cm wide. It contains 6±9 seeds, amounting to about 60 wt% of the pod. Green pods are used as cattle fodder and as a vegetable by poor people. Ripe and dry pods can no longer be eaten and empty pods have no commercial value. The yield per ha can be as high as 1,800 kg of pods. On the subcontinent harvesting is done manually and the seeds are recovered by mobile threshing machines. Guar seeds as such are not exported, neither from India nor Pakistan. 100 seeds weigh 2.4 to 3.7 g. The seed yield per plant is a maximum of 50 g.2 On its convex periphery, the guar endosperm of Cyamopsis tetragonoloba seeds has four layers of aleurone cells with a total thickness of 0.1 mm, the only living cell layers of the endosperm (Fig. 10.1), which can also synthesize enzymes similar to those mentioned above for the carob endosperm.3 The endosperm of fenugreek (Trigonella foenum graecum) seeds also has an aleurone layer as the outer cell layer of the endosperm, which can synthesize the required enzymes for germination. The endosperm of tara (Cesalpinia spinosa) seeds is morphologically similar to that of the carob kernel, but the cell structures differ and can be distinguished microscopically. The hard, compact endosperm of all four seeds contains more than 88 wt% of galactomannans on a dry basis. The endosperm of the guar seed, for instance, develops alongside the embryo or germ and completely envelops it. The endosperm itself is protected by a seed coat (see Fig. 10.2). The germ of the carob kernel is sandwiched between two endosperm halves, but without being completely enclosed by a thin film of endospermic cells. The hard coat of the carob kernel provides the desired protection, and the same is also true for the tara kernel. The seed endosperm contains very little cellulose and no lignin. The galactomannans derived from these four seed sources are composed entirely of linear (1!4)- -D-mannan chains with varying amounts of single Dgalactose substituents linked to the main backbone by (1!6)--glycosidic bonds (Figs 10.3 and 10.4). These polydisperse galactomannans can easily be distinguished from each other by their overall mannose-galactose ratios between 1.1:1 and ca 3.5:1. The galactomannans of carob bean gum have a galactose content of 17±26 wt%, those of tara gum ca. 25 wt%, guar gum 33±40 wt% and fenugreek 47±48 wt%. The large amount of galactose side stubs of about 20±48 wt% prevents strong cohesion of the main backbones of different neighbouring macromolecules, so that no extensive crystalline regions can be formed. Water at room or elevated temperatures can thus easily penetrate between the single molecules to hydrate or dissolve the accessible gum. Substitution of the mannan chain by more than 12 wt% of galactose makes the galactomannan water soluble.4,5 The fine structure of these galactomannans can be quite irregular with respect to the distribution of the galactose units. As many as five mannose units without

232


Fig. 10.1 Photos ((a)±(c)) show magnified details of aleurone cell layers (1000, 2000, 1000). The first magnification photos below ((e)), illustrates one detail of the peripheral aleurone layer (1000); the other two enlargements ((f) and (g)) show inner endosperm cells of a fractured guar split (2000).

Galactomannans 233

Fig. 10.2 A schematic cross section of guar seed. The endosperm consists of aleuronic cell layers attached to the inner endosperm. The number of mechanical purifications determines the yield of the split quality, each purification abrades more parts of the splits away, i.e. of SPS, DPS and of TPS (as imagined by the hypothetic intersection lines within the lower endosperm half, indicated by the widths between the arrows).

galactose side stubs in a row may occur in certain galactomannans of guar gum, and as many as 10±11 in specific galactomannans of carob bean gum. The fine structure of the polysaccharides of tara gum lies most probably between that of carob bean gum and guar gum. Figure 10.5 shows a possible model for a galactomannan of carob bean gum with about 20 wt% of galactose, with a molecular weight of 68,000 Daltons. (A similar model with a molecular weight of 3 million Daltons would require about 11 pages of this book.) The fine structure of the galactomannans of fenugreek gum does not pose a major problem since almost all mannose residues are substituted by galactose. The biosynthesis of galactomannans is very complex. The following brief cascading steps describe to some extent the probable route: · Step 1. Galacto- and manno-kinases i.e. phosphotransferases catalyze the phosphorylations of D-galactose to D-galactose-1-phosphate and of D-

234


Fig. 10.3 Dreiding model of galactomannan with 20% by weight of D-galactose free electron pairs, indicated by 2 2 dots at oxygen atom. Hydrogen bond between OH-group at C3 of D-mannose residue and oxygen of pyranose ring of neighbouring D-mannose unit (on the left side).

Fig. 10.4

Theoretical repeating units of four different galactomannans.

Galactomannans 235

Fig. 10.5 Schematic galatomannan molecule with a molecular weight of 68,000 daltons with about 20% by weight of galactose with a random distribution.

mannose to D-mannose-1-phosphate. These mono-phosphated esters are strongly activated intermediates. The esterified C1 atom of the mannose-1phosphate is the site to be linked to the growing non-reducing end of the mannan chain and the C1 of galactose-1-phosphate reacts with a primary OH group of the mannose unit, each liberating thereby the phosphate ester group. · Step 2. Uridine triphosphate reacts with D-galactose-1-phosphate to uridinediphosphate(UDP)-galactose and guanodine triphosphate with D-mannose-1phosphate to form guanodine-diphosphate (GDP)-mannose. Both esters set pyrophosphate free at this reaction. UDP and GDP are considered to be hexose transferring coenzymes to form glycosides. · Step 3. Now two different Golgi membrane-bound transferase enzymes come into action. One has probably two distinct binding sites for the coenzyme guanodine-diphosphate (GDP)-mannose, which is called the mannan synthase, and together with the co-factor, Mg-ions first elongate the nascent mannan chain each time by mannobiose. The second enzyme, a galactosyltransferase with docking sites for the coenzyme uridine-diphosphate (UDP)± galactose cooperates with the Mn-ions to introduce the side stub onto this mannan backbone, releasing the UDP and GDP for the process again. Every mannose residue in the growing -1,4-linked mannan backbone is rotated or inverted 180ë with respect to its neighbouring residue, and therefore the sites for two guanosine-diphosphate-mannose molecules, inverted by 180ë, must be available at the right position in the mannosyl-transferase. And two sites inverted by 180ë for the uridine-diphosphate-galactose units must also be present within the galactosyltransferase to enable the substitution of galactose residues to mannose residues to the growing mannan backbone. The highly specific galactosyltransferase introduces one - D-galactosyl unit only to one mannose residue, at or close to the non-reducing end of the growing chain, and another possibly to the next mannose unit, or to the following freshly condensed mannose units, inverted by 180ë, if required.6 · Step 4. The galactomannans formed are deposited in layers on the endosperm cell walls of the seeds, according to genetically programmed size and

236


architecture. It is not yet clear how this deposition should be visualized. Perhaps an electron micrograph of a fractured guar split could offer some insight (Fig. 10.1). No information has been found in the literature about how the molecular weight distribution of the galactomannans is accomplished during this reproducible synthesis. Many other questions also remain to be answered, including: `How many different galactomannan chains are synthesized simultaneously in one seed?' and `Does the time of day and temperature affect the size of the synthesized macromolecules?'. · Step 5. After the complete biosynthesis of the four different beans over several weeks, they are allowed to air dry naturally while still in the fields, before the pods are harvested. Synthetic and natural high molecular weight substances consist of blends of macromolecules with different degrees of polymerization. The distribution of molecular weights of these substances is therefore very important. Figure 10.6 shows these Mw distributions for carob bean gum, guar gum and xanthan gum. It

Fig. 10.6

GPC chromatogram of xanthan, guar and carob bean gum.

Galactomannans 237 is not uncommon for polymeric materials to contain macromolecules ranging in molecular weights from a few hundred to several million Daltons.7,8 In 1948 Kubal and Gralen published the average molecular weight of carob bean gum as 310,000 Daltons, which was determined at 20 ëC with ultracentrifugation.8 However, the investigated non-industrial sample of their test substance of carob bean gum in 1948 was prepared on bench scale in their laboratory and had an intrinsic viscosity [] of 5.0 dl/g. Current industrial carob bean gum products (E410) now on the market have intrinsic viscosities of about 12.0 dl/g, thus significantly higher than that used by Kubal and Gralen. Hui determined a molecular weight of 1,900,000 Daltons for a selected quality of guar gum, according to the same ultracentrifugation method at 25 ëC.9 If Hui had used a more realistic value for the partial specific volume, this average molecular weight would have increased to 2,200,000 Daltons. Industrial guar products (E412) now on the market show intrinsic viscosities of 0.7±15.0 dl/g, which correspond to apparent viscosities of aqueous solutions at 2 wt% concentration (based on 10% of moisture) of about 5 to 100,000 mPa.s, if measured with a Brookfield RVT viscometer, at 20 rpm at 25 ëC after full hydration. Since 1998 EC and FAO/WHO specifications for the molecular weight of carob bean gum (E410) used as a food additive have required a range of approx. 50,000±3,000,000 Daltons. For guar gum (E412) these specifications call for molecular weights between 50,000 and 8,000,000 Daltons.

10.3

Manufacture

Commercial gum products do not always consist of pure endosperm, but may contain residual hull and germ parts. Trade products are specified mainly according to moisture content, viscosity of aqueous solutions, protein content, acid insoluble residue (an indication of the residual hull content) and particle size distribution. To extract the endosperms from the seeds, the hull must first be removed as carefully as possible, either by mechanical or physical means. If the seed coat is removed chemically, as might be the case for carob and tara kernels, an efficient washing step with water is needed, followed by a drying process. Then the airdry peeled seeds are split. In guar seed technology, the seeds are already cracked, after which most of the friable germ and other fines can be screened off. Additional purification cycles are normally needed for the guar split. Seed varieties, weather conditions during growth and harvesting, geographical influences, different morphological structures of the endosperm, and processing conditions make an exact definition of trade products difficult. 10.3.1 Carob bean gum The evergreen carob tree can be planted in semi-arid or subtropical zones and grows in calcareous soils. These trees are important for the vegetation of the

238


entire Mediterranean area, preventing too much erosion of the soil, especially in Morocco and Portugal. The carob tree can grow as high as 10±15 m and its roots can reach a depth of 25 m. It can live for more than 100 years. Grafted carob trees can be interplanted with olives, grapes, almonds and barley in low-intensity farming systems. They are also grown as ornamentals and for landscaping, windbreaks and afforestations.10 The carob tree normally yields fruits after 8±10 years and the fruits, i.e. the pods, can be harvested once a year. The pods are 10±30 cm long, 1.5±3.5 cm wide and 1.0 cm thick. They are dark brown in colour, and straight or curved in shape. The pods contain 8±12 seeds or kernels, but exceptionally up to 15 kernels. The fruits are collected when they have a moisture content of 12± 18 wt%. They are shaken from the trees with long stakes. The fruits are then dried. The dry pods are leathery. The kernels are released in a kibbling process, as described in Section 10.2. The hull is without much value. The germ contains about 50 wt% of protein and is used as cattle feed. It is also used as a colouring agent for certain Japanese noodles and in cookies, etc. To obtain the endosperm halves, it is necessary to remove the very hard hull of the seeds in a process called `peeling' before separating the fragile germ. There are two different peeling processes: 1.

2.

Chemical peeling process: The hull is carbonized by concentrated sulphuric acid solutions at high temperature. The advantage of this technology is an even peeling effect, allowing the production of white powders. The process also facilitates the separation of the germ from the endosperm halves. Thus, high-grade qualities of carob bean gum with high viscosities can be made. The disadvantage of this technique is the effluent problem. Thermal mechanical peeling process: The kernels are roasted at temperatures of up to at least 550 ëC, so that the hull pops off to a large extent. The residual hull fragments are rubbed off mechanically. As this also leads to a simultaneous cracking of some endosperm halves and germ parts, a clean separation of endosperm halves and germ/hull parts becomes more difficult. The advantages of this technology are that it requires only relatively simple production equipment, no special effluent treatment and that the yield is high. The disadvantages are that these carob bean gums show a somewhat lower quality and lower viscosity, all having a very light-yellowish colour due to a small amount of residual germ particles.

The endosperm halves of the carob kernel recovered by both these techniques are then ground to the desired fineness. Special technology produces coldswelling carob bean gum, attaining at 25 ëC at least 60% of the viscosity of solutions prepared at 86±89 ëC for 10 minutes. Four such cold-swelling products have been developed with viscosities between 20 and 1,800±2,000 mPa.s, dissolved in water at 25 ëC, and with their `hot' viscosities between 25 and 3,000 mPa.s, dissolved at 86±89 ëC for 10 minutes, at 1% concentration. The same techniques used for carob kernels can also be used for tara seeds. The yield of high-grade tara gum is only 21±22 wt%, due to stringent food law

Galactomannans 239 specifications with respect to protein content. The EU specification for the protein content of tara gum (E417) is 3.5 wt% (N% 5.7), thus much lower than the specifications for carob bean gum of 7 wt% and guar gum of 10 wt% (both N% 6.25). Tara gum, therefore, is the most purified of the three sources and one consequence of this is that a lower yield must be accepted. The above-mentioned 22 wt% of endosperm in the composition of the tara kernel can most probably be increased to about 28 wt%, with the hull and germ content adjusted as well. (The analysis of these galactomannan seeds is very difficult when one takes into account the manual separation of the seed components after the swelling of the seeds in water, followed by dehydration in an organic solvent.) The tara tree or shrub is native to the Cordillera region of Bolivia, Peru and northern Chile and also grows in Ecuador, Colombia, Venezuela and Cuba. 10.3.2 Guar gum Guar gum is the name of the ground endosperm halves, called guar splits, which are recovered from the seeds of the guar plant Cyamopsis tetragonoloba L. This plant is an annual summer legume that grows mainly in arid and semi-arid zones. It has deep, fibrous tap roots. It enriches the soil with nitrogen and is an ideal rotation crop with cotton and grains. Guar has been grown for centuries in the Indian subcontinent and is used as human and animal food. The word guar comes from the Sanskrit word `Gau-ahar', in which `gau' means cow and àhar' indicates food. Unlike the seeds of the carob tree, which are called kernels, guar seeds are in fact called seeds. The appearance of guar seeds and the guar pod can be seen in Fig. 10.7. The colour of the seeds varies from light amber to yellowish green to grey olive. Black seeds are the result of the onset of decomposition due to microbiological attack, induced by rain at the wrong time. Black seeds cause problems at the manufacturing stage with regard to specks and the colour of the finished powder. The average total quantity of guar seeds worldwide is estimated at about 500,000 tonnes p.a. However, large fluctuations of annual availability occur, mainly due to weather conditions. In order to become less dependent on these fluctuations and to meet the constantly increasing demand for guar products, agronomy programmes have been carried out in different parts of the world, especially in the southern hemisphere. Plantings have been made in Malawi, Australia, Colombia, Brazil and Argentina. Guar grows particularly well in parts of Texas, Oklahoma and Arizona. In Texas the harvest is carried out mechanically. The key factor for the success of all agronomy programmes outside the Indian subcontinent is economic conditions. Guar seeds are composed of 20±22 wt% of hull, 44±46 wt% of germ and 32± 36 wt% of endosperm on an absolute dry basis. Table 10.2 provides an analysis of guar seed components with regard to protein content, ash and moisture content, acid insoluble residue (AIR), matter extractable in ether and calculated

240


Fig. 10.7

Guar pods and seeds.

gum content, which is defined as [100 wt% ÿ (wt% protein wt% moisture wt% AIR)]. The AIR is determined after hydrolysing the products for 6±8 h in 0.4N H2SO4 at boiling temperature. The germ contains about 50±55 wt% of protein and is sold as protein-rich cattle fodder, after reduction of the amount of trypsin inhibitor to an acceptable level. Figure 10.8 shows swollen pure guar seed components. 10.3.3 Production of guar splits and guar gum powder The whole seeds can be fed into an attrition mill or any other type of mill with two grinding surfaces travelling at different speeds. The seed is split into the endosperm halves covered with hull, called the crude crack and fine germ material, which can later be sifted off. The crude crack is heated to soften the Table 10.2

Composition and chemical analysis of guar seed components Composition of each portion

Seed component

Weight fraction, dry matter

Hull Endosperm Germ

20±22 32±36 44±46

Protein

Ash

Moisture

AIR

%

Ether soluble %

%

%

%

Gum content %

5.0 5.0 55.3

0.3 0.6 5.2

4.0 0.6 4.6

10.0 10.0 10.0

36.0 1.5 18.0

49.0 83.5 16.7

Galactomannans 241

Fig. 10.8 Main seed components of guar seed. Germs are seen in upper left corner and swollen endosperm halves and overlapping edges in upper right corner. Hand-picked hull fragments are shown in the lower middle.

hull, after which it is fed into a mill which can either abrade the hull from the endosperm, or into a hammer mill, where the hull is shattered away. Any remaining germ particles are pulverized during this step and after a further sifting the resulting splits are essentially pure endosperm. The fine material, also containing the thin part of the endosperm which overlaps the small edges of the two cotelydon leaves and the radicles, is called guar meal and is marketed as cattle feed. It should show a minimum protein content of 35 wt% (N% 6.25). The guar endosperm or guar splits are processed to commercial powdered products by hydration, flaking if needed, milling-drying and screening techniques. Single-, double- and triple-purified splits are available on the market. The endosperm of the guar seed consists of solid cell material and a split for high-grade guar products weighs 4±6 mg, whereas the endosperm half of the carob kernel shows a weight of 50±60 mg. The latter has a dense fibrous cell structure, significantly different from guar splits. The guar splits are hydrated to different extents and might be flaked and then flash ground. The powdered product becomes sifted and the coarse fraction is recycled to a mill. The finer fractions are blended in order to meet the specifications for particle size distribution, protein, AIR, ash content and viscosities. Guar is derivatized to supply the appropriate technical industries with hydroxyl-propyl-, hydroxyl-ethyl-guar, carboxy-methyl-hydroxyl-propyl guar, carboxy-methyl guar and cationic guar, as well as cationic hydroxyl-propyl guar, hydrophobic guar and guar phosphates (Fig. 10.9). Guar is depolymerized with heat and acid, with alkaline hydrogen peroxide, enzymatically by electron

242


Fig. 10.9 Guar derivatives.

beams, by alkali in the presence of air at elevated temperatures and by irradiation with gamma rays. Patented economical processes show that the quality of current guar products can be improved considerably. Such products can be used if high clarity aqueous solutions are required. 10.3.4 Production of fenugreek gum Fenugreek (Trigonella foenum graecum L.) is an annual plant species with a height of up to 60 cm, belonging to the Fabaceae family. It is a multi-purpose legume that can be grown for the spice and pharmaceutical markets, or for green manure. It produces seeds which contain another kind of water-soluble galactomannans. These polysaccharides consist of mannan chains, of which almost all mannose units are substituted with single galactose residues. The weight of an Australian fenugreek seed is 13±17 mg and that of Canadian seeds 18±22 mg, whereas guar seed weight varies from 24 to 37 mg. Fenugreek seeds are 4±6 mm long and about 2±3 mm wide with a deep groove in the middle, giving them a hooked appearance. The ground seeds have a bitter taste and a special smell. Dry toasting of the seeds can enhance the flavour and reduce the bitterness. Small amounts of toasted ground fenugreek seeds should be found in any good curry powder. The fenugreek plant is native to the Mediterranean region. It has been grown in the Near and Middle East, Africa and India, and today is grown all over the world.

Galactomannans 243 Patent number WO2004048419 filed by Air Green Co. Ltd (JP) in 2004 shows that the recovery of fenugreek endosperms can be achieved exclusively by physical procedures. The seed hull and germ are separated from the endosperms mechanically, presumably in a similar way to the production of the guar split, but also bearing in mind that the germ in the fenugreek seed is much more fragile than its hard endosperm. Morphologically, the embryonic radicle occupies a great deal of space within the seed and is covered by the hull and a thin endospermic film, which most probably becomes cracked away from the rest of the seed. The hull remaining on the main endosperm might also be partially torn off at the first grinding step. The different components of the seed can then be classified by screening. The crude endosperms can be further purified to meet the required specifications and the ground endosperm produces the desired grade of fenugreek. Another technique, described in Patent No. CA2206157 (1998-11-26) by Emerald Seed Products LTD (CA), uses extraction of the galactomannans from the endosperm in water, then clarifying the extract and precipitating the dissolved gum with an alcohol, like ethanol. The alcohol-wet precipitate can be dehydrated and purified with more alcohol, then dried and ground to the desired fineness. Approximately 25 wt% of Canadian fenugreek seed is recoverable pure endosperm gum.

10.4

Technical data

The functionality of galactomannans is mainly due to their ability to change the rheology of aqueous systems. All four types described above are very efficient thickening agents in aqueous systems and can interact, if present, with agar-agar, Danish agar, carrageenans and xanthan gum to become more efficient with respect to thickening power, or to fortify three-dimensional stabilizing structures. The thickening power of galactomannans depends, of course, upon the size or length of the dissolved substituted mannan chains. Guar gum has the highest thickening power, followed by tara gum. Both carob bean gum and fenugreek gum show a somewhat lower viscosity than tara gum. Guar gum containing galactomannans with galactose contents of 33±40 wt% is soluble in water at 25 ëC, provided the gum is accessible to the solvent water. The majority of galactomannans of carob bean gum with galactose contents of about 17±21 wt% need heat treatment of 10 minutes at 86±89 ëC, while stirring to dissolve in water. If the galactose content of the galactomannans of guar gum is decreased enzymatically to less than 12 wt%, the final products become insoluble even in hot water. All natural galactomannans are non-ionic. The hydroxyl groups can be derivatized and thus can provide non-ionic, anionic, cationic and amphoteric derivatives. The primary and secondary hydroxyl groups show practically more or less the same reactivity. Random distribution of substituents is usually obtained. The galactose side stubs each have one primary and three secondary

244


OH-groups, the substituted mannose unit two secondary OH-groups, and the unsubstituted mannose has two secondary and one primary OH-group. The maximum average degree of substitution (DS) is, therefore, three. The introduction of more than one substituent to one hydroxyl group leads to a molar substitution. Galactomannans are susceptible to strong acids, organic acids like citric, acetic and ascorbic acid, for instance, to alkali in the presence of air and strong oxidizing agents, especially at elevated temperatures, and also to electron beams and towards irradiation with -rays, so that depolymerizations of the galactomannans can be achieved to different extents or may occur randomly. Both mannose and galactose contain vicinal secondary cis-hydroxyl groups, on 2, 3 and 3, 4 respectively. These vicinal cis-hydroxyl groups form cyclic complexes with appropriate reagents (such as borate). Semi-dry processes, therefore, allow the production of derivatives and modified products, which can be water-washed if required. The removed impurities and dissolved gums in the effluent can be treated anaerobically to produce methane, which is a welcome additional energy source for the factory. Figure 10.9 illustrates some of the guar derivatives available. New patented technologies enable the production of ionic, non-ionic and amphoteric guar products, which upon dissolution in water yield water-clear solutions, even at an actual DS of about 0.1. Purified non-derivatized guar products are available for food applications. Dissolved in water, they also yield solutions of excellent clarity. More than 90% by weight of the available carob bean gum and tara gum are no longer derivatized. These products are used as straight gums as food additives in the food and pet-food industries. Table 10.3 summarizes some characteristics of two high-grade carob bean gums. The powdered guar products are specified for the viscosity of the fully hydrated solutions, according to a specified method (but not an optimal one) and mesh analysis. The other specifications of wt% of H2O, wt% of protein, wt% of AIR, wt% of ash and pH of 1 wt% aqueous solutions are respectively 12, 5, 3, 1 wt% and 6.5 for guar M100, M175, M200 and M225. Guar CSA 200/50 has slightly less protein and less AIR. The minimum viscosity of these guar products is respectively 3,000 mPa.s for the first three gums, and 3,600 and 5,000 mPa.s for the other two. The viscosity of the aqueous solutions, prepared at 25 ëC, of the two tara gums M175 and M200 at 1 wt% concentration are both 3,000 mPa.s. Prepared at 86±89 ëC for 10 minutes, the coarser product has a higher viscosity of 4,400 mPa.s compared to the finer M200 type of 4,000 mPa.s. If 1 wt% solutions of a regular CBG M200 and a cold swelling CBG M200, prepared at 86±89 ëC for 10 minutes while stirring at low shear rates, are spun out at 35,000 g for 30 minutes, respective quantities of insolubles of 17 wt% and 14 wt% are found. The 1 wt% solutions of these two products, prepared at 25 ëC, contain respectively 39 and 70 wt% soluble galactomannans. Additionally, heat treatment at 86±89 ëC solubilizes 44 wt% of galactomannnans for the regular CBG and, as might be expected, much less, i.e. only 16 wt% of galactomannans,

Galactomannans 245 Table 10.3

Typical analysis of two carob bean gum

Specification

High grade CBG M175

High grade CBG M100

% H2O % protein (N% 6.25) % AIR 1% viscosity, 10 min at 86±89 ëC RVT Brookfield, 20 rpm, 25 ëC mPa.s ± M80 (max) ± M200 (max) Trace elements As, ppm Pb, ppm Cu, ppm Zn, ppm Cd, ppm

10.0±12.0 6.5 2.0 min. 3,000

10.0±12.0 6.5 2.0 min. 3,000

99% 25%

99% 10%

0.2 ca. 0.03 2.5 5.6 ca. 0.05

0.2 ca. 0.03 2.5 5.6 ca. 0.05

for the cold swelling product. This means that the latter product can stabilize systems at much lower temperatures than regular CBG, which is very important during a heat process. Certain galactomannans of carob bean gum in aqueous solutions selfassociate under defined conditions, such as at a freezing process when nanocrystalline regions of 3±5 nm can be formed, which alternate with much bigger amorphous regions. Nevertheless, it was found that a test system of this kind yields a weak gel upon thawing, and therefore carob bean gum is used as an excellent ice cream stabilizer. The company Emerald Seed Products (101 Wood Mountain Trail East, Box 149 Avonlea, SK, Canada, S0H 0C0) produces Canafen Gum, a fenugreek gum from seeds grown in Canada. Table 10.4 shows the chemical analysis of fenugreek seeds. The applications of this fenugreek gum are considered to be the same as for the other gums described in this chapter. It might be a better candidate as a healthy food ingredient. The galactomannans of fenugreek endosperms are much more resistant towards enzymatic breakdown in the digestive tract, providing the most effective fibre in retaining viscosity. The mannan chains are protected by the side stubs of the galactose units, since the mannose residues in this gum are almost completely substituted. Acid hydrolysis apparently does not reduce the viscosity of the aqueous solutions of fenugreek gum to the same extent as in the other three types: carob bean gum, tara gum and guar gum. Fenugreek gum, therefore, is an ideal ingredient for functional foods with reduced glycemic indices. The Japanese company Air Green (http://www.airgreen.co.jp/fenugreek/ index_e.html) has three grades of fenugreek on the market with different galactomannans content, i.e. one over 86 wt%, the second with 80±86 wt% and the lowest grade containing 60±80 wt%. The specifications of these products are summarized in Table 10.5.

246


Table 10.4 Chemical analysis of fenugreek seeds (source: November 2006, University of Saskatchewan) Component

% by weight

Dietary fibre Insoluble dietary fibre Soluble dietary fibre Protein Oil Ash Starch Sugar

Table 10.5 Description

45.4 32.1 13.3 36.0 6.0 3.2 1.6 0.4

Specifications of three fenugreek products, varying in gum content Over 86% gum content

80±86% gum content

Colour white or slight yellow light yellow Smell slight original smell slight original smell AIR % 3 3 Water insoluble matter % 3 3 Heavy metal as Pb ppm 20 20 ppm As 2 2 10 10 H2O % Viscosity, 1%, 25 ëC 3,400 mPa.s 3,000 mPa.s Granularity M70 M70 Protein % 5 5 Starch negative negative Fat % 1 1 Fibre % 86 80 Caloric value kcal/g 1 1 Ash % 1.5 1.5 Galactomannans % 86 80 counts per g Bacteria 300 300 counts per g Fungi 300 300 counts per g E. Coli negative negative

60±80% gum content light brown slight curry smell 5 5 20 2 10 1,000 mPa.s M100 5 negative 1 70 1 1.5 60 300 300 negative

The fact that guar is freeze-thaw stable had already been shown in 1984, whereas carob bean gum solutions generally form gels after a freezing process. A blend of these two galactomannan gums, 1:1, tends to form gels as well rather than being freeze-thaw stable.11 Details of depolymerized guar products can be found in a publication from 1990.12 The molecular weights, M, of depolymerized guar products in kDa, based on limiting viscosity data and characterized by their Brookfield RVT viscosity of 1 wt% solutions, Br 1 after full hydration, measured at 20 rpm, at 25 ëC in mPa.s, show a rather good fit with a squared correlation coefficient of 0.9874 with the following power law equation:

Galactomannans 247 M 99:072 Br 1 0:3674

10:1

The guar products investigated showed Brookfield viscosities, as described above, of ca. 17±5,000 mPa.s. A pocket calculator can be used to calculate the molecular weights in a simple way. This also holds true for the other relationships determined, described below, for the different regression parameters. Cold swelling CBG with defined Brookfield viscosities of 25±3,000 mPa.s at 1 wt% concentration were characterized by SEC (size exclusion chromatography) to determine the peak, Mw and Mn molecular weights, called M in equation 10.2.13 These molecular weights in Da (Y-axis) were plotted against the usual Brookfield viscosities Br 1 (X-axis) and the curves followed an excellent fit with polynomial equations, at least in the above-mentioned viscosity range. The general polynomial regression equation is: M a Br 1 2 b Br 1 c

R2 1

10:2

Table 10.6 summarizes the different equation coefficients and the squared correlation coefficients for the above-mentioned polynomial equation. The Brookfield RVT viscosity of high-grade carob bean gum M100 solutions in mPa.s, prepared at 86±89 ëC for 10 minutes, while stirring with concentrations, c wt%, based on 10 wt% moisture, of about 0.5 wt% to about 2.5 wt%, fits the following power law equation: Br 2992:1 c3:7507

R2 0:9979

10:3

The same potential relationship was also tested for cold swelling carob bean gum in the concentration range of 0.4±2.0 wt%, prepared at 86±89 ëC and at 25 ëC, leading to the following equation values, i.e., the theoretical viscosity at 1 wt% in mPa.s, the exponent n and the squared correlation coefficient summarized in Table 10.7. Similar data for the different depolymerized and straight guar products are also found in Table 10.8, where the word `cold' between brackets means dissolved at 25 ëC and `hot' means 86±89 ëC for 10 minutes. The curve for P150 (cold), range of concentration 0.3±3.0 wt%, was evaluated by a polynomial regression, giving a better fit, and the following regression equation was obtained: Br 1401c3 6050c2 ÿ 2896c 313

R2 1

10:4

Table 10.6 Different coefficients of the polynomial equations and the squared correlation coefficients for four solutions of cold swelling cbg of different viscosities at 1% by weight, dissolved at 86±89 ëC for 10 minutes Type of Mw Peak Mw Mn

Coefficient a

Coefficient b

Coefficient c

Coefficient of correlation R2

ÿ0.0262 ÿ0.0558 ÿ0.110

353.89 432.41 186.71

146,120 206,146 97,701

0.9996 0.9999 0.9997

248


Table 10.7 Power law data for solutions of cold swelling carob bean gum at 1% by weight in water Temperature of dissolution ëC 25 86±89

Calculated viscosity of 1% solution in mPa.s

Exponent (n)

Correlation coefficient R2

1571 2790

3.9202 3.8125

0.9999 0.9996

Table 10.8 Power law data for different guar products, dissolved in demineralized water Product type

P150 (cold) P120 (cold) P90 (cold) P60 (cold) P30 (cold) P150 (hot) P120 (hot) P90 (hot) P60 (hot) P30 (hot) P7 (hot) P50 (hot) P100 (hot) P200 (hot)

Calculated viscosity of 1% solution, mPa.s 2237 735 74 16 5642 4141 998 137 20 0.32 648 1215 2115

Exponent n

Squared correlation coefficient R2

Concentration range in % by weight

3.4577 3.5225 3.8009 3.5414 2.6188 2.7484 3.4231 3.2220 3.3844 3.4268 3.6788 3.6865 3.4673

0.9953 0.9981 0.9992 0.9875 0.9995 0.9998 0.9996 0.9896 0.9916 0.9901 0.9980 0.9976 0.9973

0.3±3.0 0.3±4.0 0.6±5.0 0.9±5.0 0.5±3.0 0.5±3.0 0.4±4.0 0.5±5.0 0.5±5.0 3.0±15.0 0.4±2.0 0.4±2.0 0.4±2.0

Fig. 10.10 Acid stability of different guar solutions at certain pHs prepared at 86±89 ëC for 10 minutes, while stirring, expressed as rest viscosity in %, based on viscosity at pH 4 times 100%.

Galactomannans 249 The acid stability of depolymerized and straight guar products, specified by the Brookfield viscosity at 25 ëC, 20 rpm at 1 wt% solutions, was tested at different pH values. The products were dissolved at the required pH at 86±89 ëC for 10 minutes and the rest viscosity was expressed by the quotient of the viscosity measured at the defined pH and the viscosity at pH 4 times 100% (see Fig. 10.10). The guar products which were purposely depolymerized at acidic pH and with heat are more stable towards acidic hydrolysis in the final applications than modified guar products obtained after an alkaline oxidation. In a liquid food system with a pH below 3.5 one must expect a certain depolymerization of the guar galactomannans, while heating at elevated temperatures. An increase of temperature of a liquid system from 20 to 80 ëC, stabilized with galactomannans, decreases the viscosity at 80 ëC by about 50%, but upon cooling to original temperature, the viscosity returns.

10.5


These thickening and gelling agents are widely used as additives in food products, mainly to make them appealing and attractive to the consumer. Furthermore, they should also improve shelf-life by binding water, control the texture, influence crystallization, prevent creaming or settling, improve the freeze-thaw behaviour, prevent syneresis and the retrogradation of starch products, maintain turbidity in soft drinks and juices and act as dietary fibres. This means that these food additives find applications mainly in convenience food, dairy products, including frozen products (ice cream), soft drinks and fruit juices, bread and pastry, fruit preserves, baby food, and as household gelling agents in puddings, flans and pudding powder, as dietary fibres, and in pet foods. They also are used in pharmaceutical and cosmetic products. Other non-food applications of galactomannans are found in the textile industry (carpet dyeing and textile printing), and in the paper, mining, explosive, drilling, construction, oil field and chemical industries. The functional properties of regular carob bean gum are listed in Table 10.9. Similar tables can also be created for guar gum, tara gum and fenugreek gum. Further examples of applications are to be found in references 11 and 12. The work of P.H. Richardson et al. is particularly informative about the behaviour of carob bean gum and guar gum in aqueous sucrose solutions.13

10.6

Regulatory status

Apart from fenugreek gum, the other three gums are approved food additives with the following E-numbers: E410 for carob bean gum, E412 for guar gum and E417 for tara gum. Fenugreek gum is on the GRAS list in the USA. It is not quite clear whether fenugreek gum should be considered as a food ingredient.

250


Table 10.9

Functional properties of carob bean gum

Function

Example

Adhesion Binding agent Body agent Crystallization inhibitor Clouding agent Dietary fibre Foam stabilizer Gelling agent Moulding Protective colloid Suspending agent Swelling agent Synergistic agent Thickening agent

Glazes, juices Pet foods Dietetic beverages Ice cream, frozen foods, bread Fruit drinks, beverages Cereals, bread Whipped toppings, ice cream Pudding, desserts, confectionery Gum drops, jelly candies Flavour emulsions Chocolate milk Processed meat products Soft cheeses, frozen products Jams, pie fillings, sauces, baby food

10.7

Use level (%) 0.2±0.5 0.2±0.5 0.2±1.0 0.1±0.5 < 0.1 0.2±0.5 0.1±0.5 0.2±1.0 0.5±2.0 0.2±0.5 10 min) and then heating the dispersion in a tubular heat exchanger to 70 ëC followed by spray drying.33 In an extrusion process, casein at 50% solids from a dewatering device can be fed into an extruder, and 25% NaOH added to form a viscous sodium caseinate. Caseinate may also be prepared by feeding dry acid casein into the extruder and reacting with 20±40% NaOH at temperatures up to 120 ëC. The caseinates are subsequently roller dried and ground to a powder of the required particle size.34 Compositional standards for caseins and caseinates are given in Table 13.5.

Table 13.5 Compositions of caseins and casein-derived milk protein products EU regulation 2921/90 EU Acid casein

EU Rennet casein

EU Caseinates

USDA

Codex Alimentarius Stan A-18-1995

Edible dry casein (acid)

Rennet Acid Caseinates casein casein

Annex I

Annex II

Annex I

Annex II

Annex I

Annex II

Annex III

Extra Standard grade grade

Protein (%, min)

±

±

±

±

88.00

88.00

85.00

95 dry basis

90 dry basis

84 dry basis

90 dry basis

Moisture (%, max)

12.00

10.00

12.00

8.00

6.00

6.00

6.00

10

12

12

Fat (%, max)

1.75

1.50

1.00

1.00

±

±

1.50

1.5

2.0

Ash (%, min)

±

±

7.50

7.50

±

±

±

±

Ash (%, max)

±

±

±

±

±

±

6.50

Max fat and ash

±

±

±

±

6.00

6.00

Lactose (%, max)

±

±

±

±

±

Max free acid

0.30

0.20

±

±

±

FIL-IDF 72:1974

FIL-IDF 45:1969

Caseinate

Acid casein

Extra grade

First grade

Extra Standard grade grade

88 dry basis

90 dry basis

88 dry basis

95 dry basis

90 dry basis

12

8

6.0

8.0

12

12

2.0

2.0

2.0

1.5 dry basis

1.5 dry basis

1.7 dry basis

2.25 dry basis

±

7.5

-

±

±

±

±

±

2.2

2.2

±

2.5

±

±

±

±

±

±

±

±

±

±

±

±

±

±

±

±

1.00

1.0

1.0

1.0

1.0

1.0

0.5

1.0

0.20

1.0

±

±

0.20

0.27

±

0.27

±

±

±

0.20

0.27

Note: Products may also be subject to microbiological testing including standard plate count, coliforms, salmonella, thermophiles, yeasts and moulds.

Milk proteins 307 13.3.2 Fractionation of caseins Industrial scale fractionation of caseins may be desirable for a number of reasons. Human milk contains - and -caseins but no -casein, making casein an attractive ingredient for applications such as infant formulae. The high surface activity of -casein makes the protein a desirable emulsifier or foaming agent. As -casein is responsible for stabilising micelles; it may find application as a stabiliser in certain milk products. Use of individual casein fractions is also a prerequisite for the generation and recovery of casein derived bioactive peptides of high purity. Essentially all methods employed for fractionating caseins are based on the association characteristics of the individual caseins. Disruption of the caseins micellar/associated structure in part or fully is necessary for fractionation of the caseins. In a micellar casein system such as milk and in a dispersion of calcium or sodium caseinate, the individual casein molecules associate via a range of forces, including hydrophobic interactions. The strength of hydrophobic interactions is temperature dependent and at low temperatures (< ~5 ëC) when hydrophobic interactions are weaker, the -casein molecules dissociate from s-/-casein complexes and exist in solution as monomers.35 -Casein can be fractionated by renneting calcium or sodium caseinate at 4 ëC; under which conditions -casein remains soluble, while s- and para--caseins precipitates and can be separated by centrifugation. Precipitation of the -casein can be achieved by warming the supernatant to 30 ëC.36 -Casein may also be fractionated from a slurried casein feedstock by cooling to ÿ10 to 14 ëC at pH 3.5±8.0 for a sufficient time to separate the slurry into a solid phase ( -casein depleted) and a liquid -casein enriched phase.37 Terre et al.38 isolated -casein by treating milk or calcium caseinate with a calcium complexing agent which dissociates all of the casein, prior to microfiltration at 0±7 ëC. The permeate was -casein enriched and the retentate was -casein depleted. This procedure has been modified to obtain, on microfiltration at 4 ëC, a -casein enriched permeate from whole casein adjusted to pH 4.2±4.6, or from sodium caseinate treated with calcium chloride to enhance aggregation of the other caseins.39,40 Huppertz et al.41 isolated -casein from renneted skimmed milk; the rennet casein curd was recovered by centrifugation, resuspended in water and the dispersion incubated at 5 ëC to facilitate -casein dissociation; the dissociated -casein was recovered by low temperature centrifugation. Murphy and Fox42 reported a method for fractionation of -casein from a dilute sodium caseinate solution by ultrafiltration at 4 ëC. The -casein was recovered from the enriched permeate by heating it to >20 ëC to facilitate polymerisation of the -casein, following by further ultrafiltration to recover the polymerised -casein in the retentate, or by precipitation of the -casein at pH 4.9 at 20 ëC followed by centrifugation. Law and Leaver43 described a method of selective precipitation of all four caseins from skimmed milk or caseinate. The skimmed milk or caseinate was adjusting to pH 11 at 30 ëC with NaOH; calcium chloride was added to a final concentration of ~0.06 M, precipitating s-/ -casein after which the pH was readjusted to 7 with HCl and the s-/ -casein was recovered by low speed

308


centrifugation or filtration. The -casein enriched supernatant was acidified to pH 3.8 to precipitate -casein which was recovered by centrifugation/filtration. The precipitated s-/ -casein was then redispersed and separated by adjusting the dispersion to pH 4.5 and 2 ëC, which yielded s-casein as a precipitate and a supernatant which on warming to 35 ëC yielded a precipitate of -casein. Chromatographic methods can be used to fractionate caseins and have been shown to be superior to precipitation techniques; 44±47 however, these chromatographic methods are not easily scaled up and require high concentrations of nonfood grade dissociating/reducing agent making them unsuitable for producing casein for human consumption. Turhan et al.48 prepared casein fractions by microfiltration of skim milk followed by anion exchange chromatography using L-cysteine as a food grade reducing agent in the eluting buffer, replacing nonfood grade reducing agents such as dithiothreitol or -mercaptoethanol. 13.3.3 Whey protein-enriched products Whey is the serum or liquid remaining after the removal of fat and casein from milk during the manufacture of cheese or acid and rennet casein. Methods for the recovery of proteins from whey have been reviewed by Marshall,49 Matthews,50 IDF,51 Morr,52 Mulvihill,16 Mulvihill and Grufferty,53 Timmer and van der Horst54 and Mulvihill and Ennis.20 These methods are summarised in Fig. 13.3 and are outlined below. Sweet whey (minimum pH 5.6) is obtained from the manufacture of cheese or rennet casein, while acid whey (maximum pH 5.1) is obtained from the manufacture of acid casein.55 Acid whey has higher mineral/ash content (increased amounts of calcium and phosphate) than sweet whey, and if starter bacteria produced the acid by fermentation of lactose, the lactose concentration is reduced. Whey and whey protein-enriched solutions are normally pasteurised using minimum temperature and holding times and maintained at low temperature to minimise microbial spoilage and physico-chemical deterioration of the proteins and other whey constituents that would affect the functional and organoleptic properties of the resulting protein-enriched products. Compositions of typical whey-derived milk protein products are given in Table 13.6. Whey powders and modified whey powders Whole whey powders containing less than 15% protein are produced by concentrating whey by evaporation alone or in combination with reverse osmosis followed by spray drying. Special methods are used to produce nonhygroscopic, non-caking wettable whey powders. Following concentration to 50±60% solids, concentrates are cooled to 30 ëC, seeded with finely ground lactose monohydrate or well-crystallised whey powder, held for several hours and then cooled to 10 ëC to crystallise lactose as -lactose monohydrate which is less hygroscopic than non-crystalline lactose glass. The concentrate may then be dried by spray-drying in a single stage process or, more commonly, by multistage processes for improved functionality of the powders. In a two-stage

Milk proteins 309

Fig. 13.3

Industrial isolation of protein products from whey.

drying process the pre-crystallised concentrate is spray dried at low temperature and post-crystallisation and final drying takes place in an external vibrating fluidised bed; in a three-stage process the second drying stage is on an integral fluid bed within the spray dry chamber and final drying is in the third stage located outside the chamber. Another three-stage process involves atomisation with primary drying in a low profile chamber, post-crystallisation and two drying stages occur on a conveyor belt system at the base of the chamber. These two- and three-stage processes produce large agglomerated particles of low bulk density that are non-hygroscopic and readily rehydratable. The mother liquor obtained as a by-product of lactose manufacture may be concentrated and spray dried as a delactosed whey protein concentrate powder containing ~30% protein. Delactosed whey powder has a high mineral content (up to 25%) that may restrict its use in certain food applications, and affect its flavour and nutritional qualities. Demineralisation by reverse osmosis, electrodialysis or ion-exchange and/or lactose crystallisation to reduce the lactose and/or mineral concentration of whey is used to produce modified whey

Table 13.6 Compositions of typical whey-derived milk protein products

Protein (min) Moisture (max) Fat (max) Ash (max) Lactose (min)

Codex Alimentarius Stan A-18-1995

Codex Alimentarius Stan-A-18-1995

DMV International

DMV International

Davisco Foods International

Davisco Foods International

Glanbia

Glanbia

Whey powder

Acid whey

WPC

WPC

WPI

WPH

WPC

WPI

Esprion 300

Textrion PROGEL 800

PiPro

BioZate 3

WPC 30

11 5.0 2 9.5 61.0

10 4.5 2 15.0 61.0

30 5 3.5 9.5 By difference

80 5 8 6 By difference

95.0 5.0 1.0 3.0 1.0

94.0 5.5 1.0 5.0 1.0

30.5 4 4 6.5 53.0

90 5 0.5

Carbery

Carbery

Carbery

Dairygold Food ingredients

Dairygold Food ingredients

Kerry ingredients

Kerry ingredients

Kerry ingredients

WPC

WPI

WPH

WPC

WPC

Whey powder

Carbelac 80

Isolac

Optipep 80

Protein (min) Moisture (max) Fat (max) Ash (max)

80 6 9 4

90 6 1 4

80 6 9 8

Lactose (min)

5

0.025 M) over the entire pH range encountered in food applications.

Milk proteins 319 Their solubility decreases at high salt concentrations due to salting out. Thermal denaturation of whey proteins occurs at temperatures above ~70 ëC; a major consequence of this denaturation is a reduction in whey protein solubility.138 The level of denaturation and subsequent insolubility at pH 7.0 and at pH 4.6 (an index of the extent of denaturation caused by processing and storage of proteinrich whey products) depends on heating temperature and time, and whey pH and ionic calcium concentration on heating. 13.4.3 Gelation and coagulation As already stated, milk undergoes gelation when subjected to a number of treatments (heating, chemical or enzymatic treatments/modifications) and usually casein is the gelling component involved. Protein gelation generally occurs due to an alteration or unfolding of the protein structure which yields polypeptide segments which are capable of specific interactions (protein-protein and protein-water interactions) resulting in the formation of a three-dimensional crosslinked network capable of entrapping large amounts of water. Limited proteolysis of milk to hydrolyse the micelle-stabilising -casein produces para--casein-containing micelles that coagulate at the concentration of Ca2+ in the milk serum. Casein micelles may also be destabilised to form gels or precipitates on mixing equal volumes of milk and ~60%, v/v, ethanol.139 Acid induced gelation or coagulation of milk produces acid gels that may or may not expel whey (synerese), depending on the pre-heat treatment of the milk. Preheating to temperatures greater than the denaturation temperature of the whey proteins (usually > 85 ëC) reduces syneresis in fermented milks, while milk used for the production of acid cheeses and caseins is heated as little as possible to promote whey expulsion. Calcium caseinate dispersions also undergo rennet gelation; however, these gels are weak and susceptible to extensive syneresis above refrigeration temperatures.10 The viscosity of casein is much higher at low pH (2.5±3.5) than at neutral pH and gel-like structures are formed at ~5% protein at temperatures below 40 ëC.140 Calcium caseinate is the only milk protein system reported to exhibit reversible thermal gelation; concentrated calcium caseinate dispersions (>15% protein) gel on heating to 50±60 ëC, on cooling the gel slowly liquefies but reforms on heating. Gelation temperature increases with protein concentration from 15±20% and with pH in the range 5.2± 6.0.141 Thermal sensitivity is generally undesirable in the preparation of soluble whey protein-enriched products; however, the property can be exploited for production of thermal gels from whey proteins, which have excellent thermal gelling properties. Characteristics of the whey protein product such as method of production, the extent of whey protein denaturation during manufacture, the contents of protein, total ash, selected minerals and other non-protein components all influence the minimum protein concentration and heating regime required for thermal gelation and characteristics of the gel formed, such as opacity, strength and elasticity or brittleness. Solution conditions such as pH,

320


ionic species present, other non-protein components added (lipids, salts and sugars) and the presence of reducing agents also influence the gelation characteristics. Depending on these solution conditions during thermal whey protein gelation, different types of gels may be formed (e.g., fine stranded gels, particulate gels) which vary in modulus/hardness, elasticity and turbidity. WPCs and WPIs possessing different gelling properties can be obtained by careful selection of whey type and manipulation of processing conditions during manufacture. Thermal denaturation of whey proteins, in appropriate solution conditions, and subsequent appropriate treatment of the cooled solution can lead to a gelling process called `cold gelation'.142 When whey protein isolate solutions of neutral pH and low ionic strength are heated at an appropriate temperature and then cooled, denaturation and possibly minimal aggregation occurs to produce whey protein polymers but gelation does not occur due to strong electrostatic repulsive forces between the polymers formed. Acidification of this cold solution using an acid precursor like glucono-delta-lactone, that slowly reacts with water forming gluconic acid, or infusion of salts into the cold solution, alters the solvent properties reducing electrostatic repulsive forces and thus results in `cold gelation'.143 Rapid acidification results in weak brittle gels while slower acidification allows increased exposure of the free thiol groups at the surface of the polymers, increasing disulphide bond formation between aggregates and hence strengthening the gels.144±146 Enzymatic gelation of milk proteins, other than rennet (chymosin) gelation, may be induced by either protein crosslinking by transglutaminase or by specific hydrolysis using proteolytic enzymes. Transglutaminase induced gelation occurs because the enzyme catalyses the transfer reaction between the amide group of glutamine and an -amino group of lysine, crosslinking the protein molecules via the formation of covalent intra- and intermolecular isodipeptide bonds.147 Proteolytic enzyme induced gelation occurs because specific enzymatic hydrolysis of the protein is followed by ordered aggregation of the hydrolysed products to form a gel network.148 In enzymatically induced gelation of whey protein, rate of gelation and gel strength are dependent on protein concentration, pH, ionic strength and level of protein denaturation.149 13.4.4 Hydration properties The ability to hydrate and thus bind or entrap water is an important functional property of dairy proteins in food applications. The level of hydration is highly dependent on the protein composition, conformation, concentration, pH, salts, the number of exposed polar groups, surface polarity and topography as well as processing conditions, including drying procedure and storage conditions.125 The level of hydration depends on the particular products; reported hydration values for casein micelles range from 1.4 to 6.4 g H2O/g, for caseins/caseinates range from 0.7 to 3.8 g H2O/g and for individual native whey proteins range from 0.32 to 0.60 g H2O/g. Generally sodium caseinate is capable of binding more water than calcium caseinate or micellar casein particularly at high pH.

Milk proteins 321 Reported values for the water sorption capacity of several milk protein products in a model flour dough system range from 0.96 to 3.45 g H2O/g of product. Depending on the environmental conditions, thermally denatured whey proteins can have a hydration of over 10 g H2O/g; this is a result of an increase in exposed protein surface area on denaturation and thus an increased availability of hydrogen bonding sites.127 When whey protein solutions of sufficient protein content and suitable solution conditions (pH, ions, etc.) are heated, gels are formed and the water holding capacity of such gels make significant contributions to the texture and rheology of a number of processed foods. 13.4.5 Viscosity Caseinates form highly viscous solutions at concentrations >~15%; this is due to hydration and swelling which increase the hydrodynamic volume, and polymerpolymer interactions, both of which increase resistance to flow and thus viscosity. Below 12% w/w, caseinates are reported to exhibit Newtonian flow while above 12% w/w, flow becomes more pseudoplastic reflecting increasing protein-protein interactions.150 The viscosity of solutions containing >~20% protein is so high that processing is difficult even at high temperatures.25 The viscosity of sodium caseinate increases logarithmically with increasing concentration, while there is a linear relationship between log viscosity and the reciprocal of absolute temperature.42,141,150 Sodium caseinate viscosity is also very pH-dependent, with minimum viscosity occurring at ~ pH 7.0. By increasing the pH towards 9, an increase in viscosity is observed due to an increase in strong localised inter-molecular interactions. Above pH 9 the casein molecules tend to behave as separate entities and thus viscosity decreases rapidly. The viscosity of casein is also much higher at low pH (~2.5±3.5) than at neutral pH, and gel-like structures are formed at >5% protein at temperatures below 40 ëC. Caseinates exhibit pseudoplastic rheological behaviour and are thixotropic at high shear rates. Calcium caseinate exhibits a lower viscosity than sodium caseinate at the same concentration and ionic strength indicating that the cation present has a significant effect on the viscosity of caseinate (Na > K > NH4).151 The viscosity of caseinate containing 1% calcium shows unusual temperature dependence; it decreases sharply in a curvilinear fashion with increasing temperature from 30±38 ëC, then remains constant up to ~57 ëC, above which the solution gels at pH 5.4 but not at higher pH values. The relationship between viscosity and temperature depends on protein concentration, pH and [Ca2+].141 Low levels of added calcium increase the viscosity of sodium caseinate above pH 7.0 but below this pH and at sufficient calcium addition level micelle formation tends to decrease the viscosity. Manufacturing conditions also affect the viscosity of casein/caseinates. Excessive heating of milk prior to casein manufacture or of casein curd during drying ultimately leads to increased caseinate viscosity. Precipitation at pH values lower than normal (~ pH 3.8) and especially at higher pH values (~ pH 5.05) also increases the viscosity of caseinates. Roller dried caseinates

322


generally exhibit higher viscosities than spray dried caseinates. Solubilised conventional co-precipitates are more viscous than sodium caseinate and their viscosity increases with increasing calcium concentration, while solutions of total milk protein have viscosities intermediate between those of sodium caseinate and conventional co-precipitates. A logimetric decrease in viscosity of medium calcium co-precipitates containing 1% calcium was reported on increasing temperature; however, the co-precipitate viscosities were far less sensitive to temperature than caseinate viscosities. Increasing the calcium concentration in co-precipitates increases the tendency for gelation at pH 8 and above at ~30 ëC.152 Solutions of non-denatured whey proteins are much less viscous than caseinate solutions. They exhibit minimum viscosity around their isoelectric point (pH ~ 4.5); while an increase in pH (6±10) slightly increases viscosity.150 The viscosity of whey protein solutions is temperature dependent and relative to water, their viscosity decreases between 30±65 ëC, but increases at higher temperatures as a result of thermal denaturation of the globular proteins. WPC solutions containing 4±12% protein are reported to exhibit Newtonian flow while at higher concentrations flow becomes pseudoplastic and at 18±20% yield values are observed. At higher concentrations (>35% w/w), WPC solutions exhibit time-dependent shear thinning behaviour (thixotropic). In general, the addition of salts has little effect on the viscosity of whey protein solutions with the exception of CaCl2 which significantly increases the viscosity.153 13.4.6 Surface active properties Milk proteins are strongly amphipathic and exhibit good surface active properties: they adsorb readily at surfaces/interfaces decreasing surface tension and forming surface/interfacial films via complex intermolecular interactions and thus impart structural rigidity with variable rheological properties. The order of surface activity reported for the individual milk proteins is -casein > monodispersed casein micelles > serum albumin > -lactalbumin > s-casein -casein > -lactoglobulin > euglobulins.154 Sodium caseinate depresses interfacial tension more effectively than whey protein, blood plasma, gelatin or soy protein as it diffuses more quickly to an interface and on reaching the interface adsorbs more quickly than the other proteins.155 At low protein concentrations sodium caseinate spreads as a thin film with a slightly lower surface coverage than whey protein due to the greater flexibility of the caseins compared to the globular whey proteins, which because of their globular structure tend to absorb as a thicker film on the surface. Aggregated milk protein products such as MPC and calcium caseinate have a limited ability to spread at a surface as the aggregate structures are maintained by calcium bonds and/or colloidal calcium phosphate156 and this leads to the formation of a multilayer structure which has high surface dilatational modulus/viscosity. Partially heat denatured whey proteins are capable of binding ionic calcium leading to aggregation; these aggregates are much more readily absorbed at a

Milk proteins 323 surface than native whey proteins and therefore have enhanced surface activity.157 Limited hydrolysis of milk proteins generates more flexible amphiphilic peptides with a sufficient molecular weight to form stable films at the interface.111 Hydrolysis of sodium caseinate by plasmin (to produce caseins and proteose peptones) greatly increases its surface activity. The 2- and

3-caseins are small, very hydrophobic peptides and thus are very surface active. Surface films of sodium caseinate or -casein are much more flexible and less viscoelastic at both oil/water and air/water interfaces than films of lactoglobulin, -lactalbumin or bovine serum albumin. 13.4.7 Emulsifying and foaming properties Milk protein products in general, and caseinates especially, are very good fat emulsifiers and are widely used in emulsifying applications in foods. Sodium caseinate stabilised soybean oil emulsions, prepared in a valve homogeniser, exhibited lower creaming stabilities than similar emulsions stabilised by either WPC or soy isolate.158 Highly dispersed sodium, ammonium and low-calcium caseinates showed higher emulsifying capacities than more aggregated highcalcium caseinate and ultracentrifugal (micellar) caseins, while the emulsions formed using the latter were more stable than those stabilised by the highly dispersed caseinates. For all the proteins studied the fat surface area formed on emulsification increased (i.e. globule size decreased) with increased power input during emulsification and the extent of the increase was inversely related to the degree of aggregation of the emulsifying caseins/caseinates. The emulsions formed using aggregated caseins/caseinates had greater protein loads at the interface (mg/m2) than for the dispersed caseinates and protein load was directly related to emulsion stability.159 Heat treatment (>120 ëC) of sodium caseinate solutions has been shown to reduce emulsifying properties while improving foaming properties of the caseinate.160 Caseinates generally produce foams with higher overruns but lower stability than foams produced using egg white or WPC and WPI. Whey protein-enriched products are widely used in foaming applications in foods. The foaming properties of WPC increase with solids content, with an optimum of ~10% total solids. Factors such as protein concentration, level of denaturation, ionic environment, protease peptone level, pre-heat treatment and especially the presence of lipids in the WPC or WPI influence whipping properties. The foamforming capacity is enhanced by partial hydrolysis of the proteins; however, hydrolysis tends to reduce foam stability.10 Milk protein ingredients have been specifically modified to improve their foaming and emulsifying properties. Crosslinking of milk proteins with the enzyme transglutaminase produces a polymerised protein; the degree of polymerisation is directly related to an increase in the size of droplet formed on using the modified protein as an emulsifier; however, polymerisation improves emulsion storage stability by increasing the surface shear modulus/ viscosity, thus forming a solid-like protein gel around the emulsion droplets.128

324


Attachment of polysaccharide to casein/whey protein via a conjugation reaction improves the emulsifying properties of the protein; the conjugated protein molecules form a more bulky polymeric layer on the droplet surface, with the polysaccharide portion protruding outwards into the emulsion's continuous phase providing better steric stabilization.161 Limited enzymatic hydrolysis of milk proteins generates peptides that are more amphiphilic, have less secondary structure and are more flexible than the native intact protein; thus a limited degree of hydrolysis confers good foaming and emulsifying properties on protein hydrolysate ingredients. Casein hydrolysates (degree of hydrolysis, DH, 1±10%) and whey protein hydrolysates (DH, 10±20%) diffuse rapidly, and absorb at the interface reducing the droplet size on emulsion formation, but these hydrolysates are less efficient at stabilising emulsions because of their limited ability to form stable surface films.111 Emulsions prepared with hydrolysates are less stable to reduction in pH or alcohol addition but more stable to calcium ions.162 Extensive hydrolysis of milk proteins generates low molecular weight peptides and free amino acids, resulting in milk protein ingredients which decreased ability to form and stabilise emulsions in comparison to the intact native proteins.162±164

13.5

Biological activity of milk protein products

Milk proteins are a source of nitrogen and amino acids which are essential for the growth of the neonate and for the maintenance of various bodily functions; in addition, intact milk proteins have some important biological activities. Milk proteins have an ability to bind small hydrophobic vitamins such as retinol (vitamin A),165 folate166,167 and cyancobalamin (vitamin B12).168 This binding may improve the absorption of these vitamins in the intestinal tract169 as it may protect the vitamin against the possibly detrimental environmental conditions during passage through the digestive system thus improving the bioavailability of these vitamins. Milk proteins are a rich source of biologically active peptides which are encrypted in their primary sequence; these biologically active peptides are latent until released on hydrolysis of the intact proteins. These peptides show a wide variety of biological activities including opiate, antithrombotic, antihypertensive, immuno-modulating, antibacterial and mineral carrying properties.170 13.5.1 Biological activity of intact caseins In addition to providing nitrogen and essential amino acids for growth, the principle biological function proposed for casein is to transport high levels of calcium to the neonate in a manner that prevents pathological calcification during its transport through the mammary gland.171 s1-Casein enhances mitogen-stimulated proliferation of murine splenic T-lymophocytes in vitro.172 -Casein enhances the mitogen induced proliferation of ovine T and B

Milk proteins 325 lymphocytes in a dose-dependent manner.173 The glycomacropeptide of casein exhibits an immunosuppressive effect, with those macropeptides containing high levels of N-acetylneuraminic acid showing strong activity against T-lymphocytes.174 13.5.2 Biological activity of intact whey proteins Whole whey protein and intact individual whey proteins have been shown in vitro to modulate lymphocyte functions, suppressing T-lymphocyte mitogenesis in cell cultures.175,176 A whey protein diet has been shown to have a protective role against the development of tumors in the GI tract as well as selectively inhibiting cancer cell growth.177,178 The principle biological function of -la is to act as a coenzyme in the synthesis of lactose,9 while its immunomodulatory and anticarcinogenic properties have also been reported on.178,179 -Lg has been shown to act as a carrier for hydrophobic and amphiphilic molecules including retinol; it is proposed that it protects these molecules from oxidation during transportation through the stomach to the small intestine; -lg may also stimulate lipolysis by binding free fatty acids; it also shows immunomodulatory activities.180,181 -Lg chemically modified using 3-hydroxyphthalic anhydride (3-HP) has antiviral activity; it has been shown to be effective in inhibiting HIV-1 infections in humans.182 BSA functions as a carrier protein for the transport of nonpolar molecules in biological fluids.183 Bovine immunoglobulins (Igs) provide various types of immunity including passive immunity via colostrum to the neonate. Lacteal secretions containing Igs provide an immunological protection against microbial pathogens and toxins, thus protecting the mammary gland from infection.184 Immunoglobulins include the so-called lactenins, L1 and L3, which inhibit gram-positive bacteria; L1 is particularly efficient against some strains of Streptococcus pyogenes and L3 acts against some strains of Lactococcus lactis.9 Lactoferrin (LF) is an iron chelating glycoprotein which acts as a natural nonspecific defence system for the body; it modulates the immune system by promoting inflammatory, intestinal and peripheral specific antibody response and also by controlling lymphokines production.184,185 The ability of LF to sequester iron from a relatively iron-free environment is the principle factor governing the antimicrobial, antifungal, antiviral, antioxidative and anticarcinogenic activity of LF. Its ability to create an iron deprived environment and to bind to the membranes of microbes, thus disrupting the structure, function and integrity of the cell membrane allows it to modulate the intestinal microflora.186±188 Lactoperoxidase (LP) has biological activity; it provides protection against invading micro-organisms and thus it is regarded as an indigenous antimicrobial agent.184 It exhibits a broad range of activity against various bacteria, viruses, yeasts and moulds via the LP system. In the presence of H2O2, LP oxidises the thiocyanate anion (SCN±) and certain halides producing numerous intermediary oxidation products, including the hypothiocyanate anion (OSCN±) and hypothiocyanate (HOSCN) which cause structural damage to the cytoplasmic membrane of the micro-organism.189,190

326


13.5.3 Biologically active peptides Milk proteins are proposed to be the main source of biologically active peptides; the biological activity of these peptides has been reviewed by Meisel,191 Fitzgerald and Meisel,117 Mater et al.,192 Kilara and Panyam,115 PihlantoLeppaÈlaÈ and Korhonen,184 Silva and Xavier Malcata,193 Gauthier et al.,194 Korhonen and Pihlanto,116 Nnanna112 and Gobbetti et al.124 Opioid peptides Milk protein derived opioid peptides are referred to as exorphins in order to distinguish them from naturally occurring enkaphalins, endophins and dynorphins.195,196 Opioid peptides (typically 5±10 amino acids) from casein are termed casomorphins or casoxins, while those from whey proteins are called lactorphins or lactoferroxins. The biological effect of the opioid peptides is dependent on the receptor type to which they bind; -receptors are said to control intestinal motility and emotional behaviour, -receptors control emotional behaviour and -receptors are linked to analgesia and satiety.117 A common structural trait in opioid peptides is the presence of a Tyr residue at the N-terminal of the amino acid sequence (except for s1-casein exorphin, casoxin 6 and lactoferroxins B and C), coupled with the presence of another aromatic residue, Phe or Tyr, in the third or fourth position which ensure the binding of the peptide to the opioid receptor.193 The opioid activity is also dependent on the localised negative potential in the vicinity of the phenolic hydroxyl group of tyrosine, as the removal of tyrosine results in the absence of activity.197 The most widely studied of the milk protein opioid peptides are the casomorphins which include fragments 60-63, 60-64, 60-65, 60-66 and 60-70 of the -casein amino acid sequence and act as -type ligands.198±201 s1-Casein derived opioid peptides, known as exorphins, correspond to fragments 90-96 (Arg-Tyr-Leu-Gly-Tyr-Leu-Glu), 90-95 and 91-96 and are -type receptor ligands.202,203 Whey protein derived peptides from -lactoglobulin (fragment 102-105 known as -lactorphin (Tyr-Leu-Leu-Phe) and from -lactalbumin (fragment 50-53, -lactorphin (Tyr-Gly-Leu-Phe)) are -type ligands but show a weak but consistent affinity for opioid receptors.198 Perpetuo et al.204 isolated a peptide from -casein, fragment 114-121 (Tyr-Pro-Val-Glu-Pro-Phe-Thr-Glu), which exhibited opiate activity in vitro. Milk proteins also contain opioid antagonist peptides which suppress the action of opiate agonists and humoral peptides enkephalin. These opioid antagonist peptides, referred to as casoxins, are derived mainly from -casein and are -type receptor ligands. Casoxins A and B are fragments 35-41 (TyrPro-Ser-Tyr-Gly-Leu-Asn), and 58-61 (Tyr-Pro-Tyr-Tyr) of -casein, respectively, and have a low antagonistic potency when compared to naloxone, a synthetic opiate receptor antagonist. Casoxin C is fragment 25-34 of -casein (Tyr-Ile-Pro-Ile-Gln-Tyr-Val-Leu-Ser-Arg) and exhibits high opioid antagonistic activity.205,206

Milk proteins 327 ACE inhibitory peptides Angiotensin-I converting enzyme (ACE, peptidyldipeptide hydrolase; EC 3.4.15.1) is a multifunctional, zinc-dependent carboxypeptidase, which plays an important role in the rennin angiotensin system, by influencing the regulation of peripheral blood pressure, the kallikrein-kinin system and the immune system. ACE converts angiotension I to a potent vasoconstrictor, octapeptide, angiotension II. ACE also catalyse the degradation of bradykinin, a vasodilatory peptide, and stimulates the release of aldosterone in the adrenal cortex which decreases the renal output while increasing water retention.117,184 ACE inhibition primarily results in a hypotensive effect but also affects the immunodefence and nervous systems.207 Casein derived peptide inhibitors of ACE are known as casokinins, which have been found in s1-casein (fragments 23-24, 23-27 and 194-199), -casein (fragments 74-76, 108-113, 114-121, 177-183, 193-198, 169-174 and 193-202) and -casein (fragments 108-110).117,204 s2-Casein also contains ACE inhibition peptides (fragments 189-193, 189-197, 190-197, 198-202) but these fragments have a very low activity.208,209 Whey protein derived inhibitors of ACE are referred to as lactokinins and have been found in -lactoglobulin (fragment 142-148), -lactalbumin (fragment 105-110) and bovine serum albumin (fragment 208-216).210±212 The binding of ACE is strongly influenced by the C-terminal tripeptide sequence of the substrate. Most of the potent casokinins and lactokinins contain hydrophobic amino acid residues at each of the three C-terminal positions, with proline, lysine or arginine residues being the most efficient in enhancing substrate binding to the negatively charged catalytic site of ACE. The removal or absence of arginine from the C-terminal can result in inactive ACE-inhibitory peptides.117 Immunomodulatory peptides Casein-derived immunopeptides include fragments of s1-casein (fragment 194199) and -casein (fragments 63-68, 191-193 and 193-202), which stimulate phagocytosis activity of murine and human peritoneal macrophages in vitro and exert a protective effect against Klebsiella pneumonaie infection in mice in vivo after intravenous administration.213 Coste et al.214 showed that a peptide from the C-terminal sequence of -casein (fragment 193-209) which also contains the ACE-inhibiting peptide ( -casokinin-10) induced a significant proliferation response in rat lymphocytes. Whey protein derived immunopeptides isolated from the N-terminal of -lactorphins derived from -lactalbumin (fragments 1819, 18-20 and 50-51) has in vitro enhanced the proliferation of peripheral blood lymhocytes.215 -Casein fragment 60-66 displays immunomodulatory activity; it confers a suppressive or stimulatory effect on lymphocyte proliferation of human colonic lamina propria lymphocytes (LPL), which is dependent on concentration. The anti-proliferative effect is reversed by the opiate receptor antagonist, naloxone.215 Immunomodulatory milk peptides may also alleviate allergic reactions in atopic humans and enhance mucosal immunity in the

328


gastrointestinal tract.184 It has been suggested that opioid peptides may affect the immunoreactivity of lymphocytes, because opioid -receptors for endorphins are present in lymphocytes.216 Caseinophosphopeptide The caseinophosphopeptides (CPPs) are derived from the highly phosphorylated regions of the caseins; phosphorylated peptides have been isolated from hydrolysates of s1-casein (fragments 43-58, 45-55, 59-79, 66-74 and 106-119), s2-casein (fragments 2-21, 46-70, 55-75, 126-136, 138-149) and -casein (fragments 1-25, 1-28, 2-28).217 A common motif of CPPs is that their sequence consists of three phosphoseryl residues followed by two glutamic acid residues (SerP-SerP-SerP-Glu-Glu).218,219 These phosphopeptides are stable under acidic conditions and are very resistant to further proteolysis because of the high negative charge density.170 The CPPs are capable of binding and solubilising calcium, magnesium, iron, zinc and copper.191 Their ability to sequester calcium may be considered beneficial in the prevention of osteoporosis.220 CPPs also have anticariogenic effects by promoting recalcification of tooth enamel by localising amorphous Ca2+ at the surface of the tooth, depressing demineralisation and enhancing remineralisation of the enamel.220,221 A -casein derived CPP (fragment 1-25) has been shown in vitro and in vivo to enhance the bioavailability of iron when compared to whole casein and organic salts and has been used to treat anaemia in rats.222,223 Dephosphorylated casein peptides do not bind minerals.224 Mineral binding peptides have also been found in whey protein hydrolysates (-lactalbumin, -lactoglobulin and lactoferrin). These peptides are not phosphorylated; therefore, the minerals bind to the peptides through binding sites other than phosphorylated sites; the ability of these sites to bind minerals may be influenced by peptide conformation. Also both -lactalbumin and lactoglobulin derived mineral binding peptides have shown higher affinity for iron than the native proteins.225 Antithrombotic peptides Antithrombotic peptides derived from the C-terminal, glycomacropeptide portion of -casein (fragment 106-169) are known as casoplatelins; fragment 106-116 inhibits the aggregation of ADP-activated platelets and the binding of human fibrinogen -chain to platelet surface fibrinogen receptors.115,126 Smaller peptides (fragments 106-112, 112-116 and 113-116), known as casopiastrin, do not inhibit fibrinogen binding but are capable of inhibiting platelet aggregation.226,227 Glycomacropeptide mediates the absorption of minerals (calcium, zinc or iron) and modulates the gut microflora; the carbohydrate moities (sialic acid) promotes the growth of bifidobacterium.228,229 The absence of Phe, Tyr, Trp and Cys residues in GMP makes it a suitable ingredient for the nutrition of phenylketonuria sensitive patients.19 Non-glycosylated forms of GMP, referred to as caseino-macropeptide (CMP), are reported to inhibit gastric secretions and slow down stomach muscle contractions. CMP also stimulates the

Milk proteins 329 release of cholecystokinin, the satiety hormone involved in controlling food intake and digestion in the duodenum of animals and humans.230 Antibacterial peptides Isracidin, an antibacterial peptide from s1-casein (fragment 1-23) was isolated by Hill et al.231 Isracidin strongly inhibits the growth of gram-positive bacteria at high concentrations in vitro and also confers a protective effect in vivo against S. aureus and C. albicans at low concentrations. McCann et al.232 isolated an antibacterial peptide from s1-casein (fragment 99-109), which displayed a broad antibacterial activity including activity against gram-positive and gramnegative bacteria. Casocidin-I is an antibacterial peptide isolated from s2casein (fragment 165-203) which contains a high proportion of basic amino acid residues (10 of 39) and inhibits gram-positive bacteria (S. carnosus) and gramnegative bacteria (E. coli).233 Kappacin is an antibacterial peptide found in nonglycosylated, phosphorylated CMP and has been reported to inhibit grampositive bacteria (S. mutens) and gram-negative bacteria (P. gingivalis, E. coli), as well as showing an ability to bind to enterotoxins and inhibiting bacterial adhesion and growth.234 Whey protein hydrolysates also contain peptides ( lactoglobulin fragments 15-20, 25-40, 78-83 and 92-100) which exhibit activity against gram-positive bacteria. Modification of the -lactoglobulin fragment 92100 via the substitution of Asp with Arg and the addition of a Lys residue at the C-terminus expanded the bactericidal activity to include gram-negative bacteria including E. coli.235 Lactoferricin (fragment 17-41), is an antibacterial peptide produced by enzymatic hydrolysis of lactoferrin. It inhibits a wide variety of bacteria including enterotoxigenic E. coli and L. monocytogenes, yeast and fungi by disruption of their cytoplasmic membrane.236±239

13.6

Food uses of milk protein products

Details of many of the food uses of milk protein products are proprietary to milk protein product producers and food processors and are not reported in the literature. However, reviews on the food uses of milk proteins include Southward and Goldman,240 International Dairy Federation,241 Southward and Walker,242 Otten,243 Zadow,244 Hugunin,245 De Wit,246,247 Southward,248,249 Mulvihill,16 Mangino,250 Chandan,251 Mulvihill and Ennis20 and O'Connell and Flyn.21 Milk protein products have also had applications as diverse as animal feed ingredients, plastics and industrial glues but these uses are not considered here. The following are brief outlines of some reported food applications of milk protein products. 13.6.1 Bakery products Milk proteins cannot replace wheat gluten to any great extent in bakery products. Caseins are particularly rich in lysine and so make excellent nutritional supplements for cereals, which are deficient in lysine. Casein/caseinates are added to breakfast cereals, milk biscuits, protein-enriched bread and biscuits,

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high-protein bread and cookies as a nutritional supplement and to frozen baked cakes and cookies as an emulsifier and to improve texture. The type of casein/ caseinate must be carefully chosen to be compatible with the particular bakery application. Co-precipitates are used in pastry glaze to improve colour, in milk biscuits, cake mixes for diabetics, high-protein biscuits and cookies as a nutritional supplement and in fortified bread to improve dough consistency (due to water binding by the milk proteins), sensoric properties and to increase volume and yield. However, some milk fraction has been described as loaf volume-depressing.252 Depression of loaf volume by whole whey protein products was associated with proteose peptones since fortification of dough with 1% UF-WPC caused little loaf volume depression. The concentration of whey lipids during UF also contributes to good baking characteristics. Whey protein shows economic and nutritional advantages as a replacement for eggs in cake manufacture. However, simply replacing whole eggs by WPC in madeira-type cakes results in poor quality cakes although better results are obtained if the fat and WPC are pre-emulsified. Various WPCs have been used in products like muffins and croissants to increase their nutritional value. Bakery applications of milk protein products are outlined in Table 13.7. Table 13.7

Application of milk protein products in baked products

Milk protein product

Application

Effect/property

High-calcium co-precipitate Low-calcium co-precipitate Casein

Pastry glaze, cake mix for diabetics, milk biscuits, cookies Cookies

Colour, shine, nutrition, cake volume, texture, appearance Nutrition, texture, appearance

Breakfast cereal, high-protein bread Milk biscuits, biscuits Frozen baked cake, protein-enriched milk biscuits Shortening Pie filling Powdered friable fat High-protein biscuit, fortified bread

Nutrition

Calcium caseinate Sodium caseinate

Co-precipitate Lactic casein Acid casein

Cookies Non-fat dry milk substitute

WPC

Cookies, muffins, croissants Bread Cake

Nutrition Texture, emulsifier, nutrition Fat encapsulation Stabiliser Fat stabiliser Dough consistency, sensory, increase volume/yield, fast fermentation Nutrition, texture, appearance Structure building in dough, nutrition, flavour Water retention, colour, emulsifier, nutrition Dough formation Fat binding, heat setting

Milk proteins 331 13.6.2 Dairy products Milk protein products are used to supplement the protein content in conventionally processed dairy products and in the manufacture of imitation dairy products (Table 13.8). Caseins, vegetable fat, salts and water are used to make imitation cheeses (cheese analogues), which result in significant costTable 13.8

Application of milk protein products in dairy-type products

Milk protein Application product

Effect/property

Calcium caseinate

Processed cheese spread, imitation Mozzarella cheese, imitation cream cheese

Spreadability, stretch, browning, emulsifier

Sodium caseinate

Coffee creamer, UHT cream, nondairy creamer, imitation sour cream, cultured cream

Emulsifier, whitener, texture, body, resistance to feathering, sensory characteristics, water binding, viscosity, flavour Reduce syneresis, increase gel firmness, stabiliser, consistency Emulsifier, nutrition, foaming properties, increase yield Stretch, browning, emulsifier

Yoghurt, fruit yoghurt Imitation milk, milk shakes, cheese milk Imitation Mozzarella cheese, imitation cream cheese Ice cream products Dairy-based spreads, butter-type spread, butter powder Whipping composition for drinking

Consistency, flavour, foaming, water binding, aroma Texture, emulsion stabiliser Foaming

Coprecipitate

Fat-reduced milk Spread-type dairy products Cultured milk product

Nutrition Texture Increase biological value

Potassium caseinate

Fat-reduced milk

Nutrition

Hydrolysed casein

Ice cream Yoghurt

Overrun Growth media for starter

Acid casein

Simulated cheese, cheese analogue, imitation milk

Meltability, stringiness, cost, texture, meltability, nutrition, stability

Rennet casein

Processed cheese, Mozzarella substitute, cheese analogue, cheeselike spread

Emulsifier, meltability, stringiness on melting, texture, flavour

WPC

Soft serve ice cream Cheese products

Overrun, cost, Water and fat binding, cost, emulsification Reduce lactose Casein/caseinate replacer

Yoghurt Coffee whiteners Whey proteins

Yoghurt, Quarg, Ricotta

Yield, nutrition, consistency, curd cohesiveness

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saving, compared to the use of natural cheese, when used in pizza, lasagne and sauces and on burgers, grilled sandwiches, macaroni, etc. The important functional properties of casein in this application include fat and water binding, texture enhancing, melting properties, stringiness and shredding ability. Rennet caseins, acid caseins and caseinates are used most commonly for cheese analogues although co-precipitates also have potential in this area. Sodium caseinate in powdered coffee creamers (which also contain vegetable fat, carbohydrate and emulsifiers/stabilisers) acts as an emulsifier/fat encapsulator and whitener, imparts body and flavour and promotes resistance to feathering (i.e. coagulation of cream in hot coffee solutions). These creamers are cheaper, have a longer shelf-life and, requiring no refrigeration, are more convenient to use than fresh coffee creams. Sodium caseinate is used to reduce syneresis and increase gel firmness in yoghurts, and is added to milk shakes for its emulsifying and foaming properties. Caseins/caseinates, vegetable fat and carbohydrate, e.g. corn syrup, are the principal ingredients used in the manufacture of low cost imitation milk products that contain no lactose, to which some people are intolerant. Sodium caseinate is also used as an emulsifying and fat encapsulating agent in the manufacture of high-fat powders for use as shortenings in baking or cooking. Dry whipping fats or whipping creams contain casein products while a number of butter-like dairy spreads are manufactured using milk and/or vegetable fat and various casein products. In these applications casein acts mainly as an emulsifier and in the case of dairy spreads, it also enhances texture and flavour. Whey protein products are used in yoghurts and cheeses to improve the yield, nutritional value and consistency. Yoghurt viscosity and stability are improved by replacing skim milk solids with WPC. Up to 20% of the casein in Quarg can be replaced by thermally-modified WPC to improve the yield and nutritional value. The use of sweet UF-WPC in Ricotta cheese manufacture increases the cohesiveness of the curd. Emulsions prepared using heat-denatured whey proteins and fat are used as a protein base for formulated cream cheeses and cream cheese spreads. Sliceable and squeezable cheese-type products, based on the emulsifying and gelling properties of whey proteins, are produced by heat treatment of skim milk and WPC solids dispersed in an emulsion of milk fat in WPC. Whey protein concentrates are also used in cheese filling and dips as they complement the cheese flavour and result in a soft product. 13.6.3 Beverages Casein products are used for their whipping and foaming properties or as stabilisers in drinking chocolate, effervescent drinks and beverages (Table 13.9). Sodium caseinate is used as an emulsifier and stabiliser in cream liqueurs, which typically contain cream, sodium caseinate, added sugar, ethanol, and trisodium citrate to prevent calcium-induced age gelation; it is also used to a lesser extent in other aperitifs. Sodium and calcium caseinates are used in the production of GlucernaTM and ResourceTM which are nutritional beverages produced for

Milk proteins 333 Table 13.9

Application of milk protein products in beverages


Effect/property

Casein

Clarification, colour removal, stabiliser, palatability, colour stability, removal of phenolic compounds Stabiliser

Beer, wine

Effervescent lemonade ingredient Potassium caseinate

White wine

Removal of tannins and phenolic compounds, taste, colour removal

Sodium caseinate

Apple juice Cream liqueur, alcoholic creamcontaining beverage, wine aperitif Soluble tea products Drinking chocolate

Colour removal Emulsification

Casein hydrolysate

Non-alcoholic fruit beverage

Whippability, foaming

WPC

Citrus-based beverages, soft drinks Hot cocoa beverages, chocolate drink

Flavour, nutrition, solubility Foamer, cost, colloidal stability

Prevention of `tea cream' Stabilisation

patients with abnormal glucose tolerance. Casein products have also been used as fining agents, to decrease colour and astringency and to aid in clarification in the wine and beer industries. WPCs may be added to fruit juices, soft drinks or milk-based beverages to produce highly nutritious products often marketed as `sports drinks'. For use in soft drinks, defatted WPCs with a low ash content, good solubility at pH 3.0 and a bland flavour are required. The WPC must also be resistant to physical deterioration or flavour changes during product storage and must not interact with flavour components and thereby mask the typical flavour of the drink. WPCs and WPIs are added to milk-like flavoured drinks to impart viscosity, body and colloidal stability and they are included as protein supplements in high protein powdered athlete-targeted flavoured beverages and in frozen juice concentrates. 13.6.4 Dessert-type products Sodium caseinate is used in ice cream substitutes and frozen desserts to improve whipping properties, body and texture and to act as a stabiliser and also finds use in mousses, instant puddings and whipped toppings for similar reasons and because it acts as an emulsifier and film-former (Table 13.10). In the manufacture of whipped toppings the basic ingredients of vegetable fat, sugar, protein (sodium caseinate), emulsifier, stabilisers and water are blended at 38± 46 ëC and the mixture is pasteurised and homogenised and then either cooled rapidly to below freezing point or spray dried. In ice cream manufacture, part of the skim milk solids can be replaced by whey powder, and even more may be

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Table 13.10

Application of milk protein products in dessert-type products


Effect/property

Sodium caseinate

Whipped dessert, whipping fat, whipped topping, mousse, ice cream frozen dessert, frozen puddings, instant dessert/pudding bases

Whippability, fat encapsulation, overrun, powder flow properties, replace milk solids, emulsifier, stabiliser, flavour, texture

Caseinate

Spongy dessert

Whippability, aeration

Hydrolysed sodium caseinate

Whipped topping

Freeze-thaw stability

WPC

Fruit jellies and jams Frappes, whipped toppings, frozen desserts/puddings Flan-style desserts, custards

Flavour Overrun, cost, whippability Gelling ability

replaced by using delactosed, demineralised whey powder or UF-WPC with no adverse effect on flavour, texture or appearance. WPC has also been used in frozen juice bars and in compound coatings, especially chocolate coatings, for frozen desserts. 13.6.5 Pasta products Milk protein products may be incorporated into the flour base for pasta manufacture to improve nutritional quality and texture (Table 13.11). Products fortified by addition of sodium or calcium caseinate, low calcium co-precipitate or WPC prior to extrusion include macaroni and pasta. Enrichment of pasta flours with non-denatured whey protein products results in firmer cooked noodles which are also more freeze-thaw stable and suitable for microwave Table 13.11

Application of milk protein products in pasta products


Effect/property

Sodium caseinate

Protein enriched pasta

Nutrition, consistency, binder, texture, taste, appearance

Calcium caseinate

Enriched wheat macaroni, high protein pasta

Nutrition, texture

Casein

Enriched, fortified macaroni

Nutrition, texture

Soluble low- Imitation rice calcium coprecipitate

Nutrition, texture

WPC

Flour replacer, nutrition

Pasta

Milk proteins 335 cooking. Imitation pasta-type products containing substantial proportions of milk protein have also been manufactured. 13.6.6 Confectionery Whey proteins are suitable for use in aerated candy mixtures and are incorporated as a frappe, a highly aerated sugar syrup containing the whipping protein (Table 13.12). Caseins are used in toffee, caramel, fudge and other confections as they form a firm, resilient, chewy matrix on heating and they contribute water binding and aid emulsification. WPCs are less useful in these products as they produce a softer coagulum and the high lactose content may cause crystallisation during storage. Casein hydrolysates may replace egg albumen as foaming agents in marshmallow and nougat as they confer stability up to high cooking temperatures as well as good flavour and browning properties. Use of WPC or WPI as a replacement for egg white in the manufacture of meringues produces acceptable products only when defatted products are used; in contrast the manufacture of acceptable sponge cakes requires fat-containing WPCs. A milk protein hydrolysate, `Prodiet F200', has been used in chocolate formulations; it contains a bioactive peptide with relaxing properties.253 Calcium caseinate, WPC, WPI, MPI, and milk protein hydrolysate ingredients are used in the manufacture of high protein energy bars; they are used to extend bar shelf-life and minimise bar hardening, and nutritionally to optimising muscle performance during exercise. EnsureTM, GlucernaTM and Choice dmTM are speciality nutritional bars for people with diabetes; these all contain calcium caseinate. Table 13.12

Application of milk protein products in confectionery products


Effect/property

Sodium caseinate

High protein chocolate snack confectionery bars, Aerated cake icing

Nutrition, storage stability, flavour, aeration, body, mouthfeel, texture

Hydrolysed sodium caseinate

Coated confectionery product

Nutrition

Calcium caseinate

Aerated cake icing High protein energy bar

Aeration, body, mouthfeel, texture Nutrition, improve shelf-life stability

Hydrolysed casein

Aerated confection

Whippability

Coprecipitate

Protein-rich chewable bar

Nutrition, texture

Milk protein Chocolate formulations hydrolysate

Relaxation

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13.6.7 Meat products In comminuted meat products caseins release meat proteins for gel formation and water binding and thus contribute to fat emulsification, water binding and improved consistency. Sodium caseinate is a common additive in meat applications although various co-precipitates have also been used (Table 13.13). Up to 20% of the meat protein in frankfurters and luncheon rolls may be replaced by whey proteins, which are used to prepare pre-emulsions of part of the fat and support network formation, by gelation, during subsequent cooking. Soluble, low viscosity WPCs may be used in injection brines to fortify whole meat products such as cooked hams. Injection of fresh and cured meats with milk protein solution increases yield. In addition, WPI and its hydrolytic products have been used in the preparation of cooked pork patties, where they reduce cook loss as well as inhibiting lipid oxidation during refrigerated storage.254 Casein phosphopeptides have also been incorporated into ground meat products including ground beef and have been shown to enhance product stability by inhibiting lipid oxidation.255 Lactoferricin is used in the washing of animal carcasses at refrigeration temperatures to inhibit the growth of food pathogens (e.g., E. coli 0157:H7) and spoilage micro-organsims (e.g., C. viridans). 13.6.8 Nutritional/medical/pharmaceutical applications Milk protein products are used extensively in special dietary preparations for the ill or convalescing, for malnourished children and for people on therapeutic or weight-reducing diets (Table 13.14). Modified low mineral whey powders are used to produce `humanised' infant formulae with a whey protein-to-casein ratio resembling that of human milk. Infant formula is supplemented with Table 13.13

Application of milk protein products in meat products


Effect/property

Sodium caseinate

Liver sausage, sausage, blood, patties, low fat meat paste

Binder, decolouriser, emulsifier

Potassium caseinate

Low fat meat paste

Emulsifier

Caseinophos- Ground meat products phopeptides

Enhance product stability, prevent lipid oxidation

Sodium salt PateÂ sausage of coprecipitate

Nutrition, sensory, cost

WPC

Cost, improved performance, water and fat binding, water solubility at low viscosity

Meat products

Milk proteins 337 Table 13.14 Application of milk protein products in nutritional, pharmaceutical and medical applications Milk protein product

Application

Effect/property

Sodium caseinate

Candy for space feeding, Carnation SlenderÕ, enriched dairy drink for infants, meat replacement

Nutrition

Calcium caseinate

Bakery products for diabetics Meat replacement, infant dietary food

Flour substitute Nutrition

Casein

Water dispersible protein, special dietary foodstuffs Toothpaste

Nutrition, texture

Acid casein

Low-sodium infant formula

Nutrition

Coprecipitate

Carbohydrate-free and low-lactose infant food

Nutrition

Highcalcium coprecipitate

Cake mix for diabetics

Nutrition, cake volume

WPC

Geriatric/hospital/liquid diets Infant formulae

Nutrition Nutrition, digestability

WPI

Nutritional protein bar/beverages

Improve immuno-defence and nervous system activity

Whey protein hydrolysate

Hypoallergenic infant formulae

Nutrition

Caseinophosphopeptides

Dental filling material

Mineral binding activity

Lactoferricin

Medication

Treatment of gastritis

Prevent caries

lactalbumin, providing a rich source of essential amino acids, in particular tryptophan and its metabolites such as serotonin, which is essential for brain maturation and development of other neurobehavioural regulations of food intake and sleep-wake-rhythm.256 Whey protein hydrolysates have been used in hypoallergic, peptide-based formulae. Fractionation of whey proteins allows the formulation of infant formulae that possess whey protein compositions more closely resembling that of human milk. -Casein and -lactalbumin enriched protein fraction together with lactotransferrin are being used as ingredients for the production of more `humanised' infant formulae. Lactoferrin is being added to infant formulae for its bacteriostatic and bactericidal activity and CMP is being added to contribute to improved mineral adsorption. Caseinates and coprecipitates are used in low lactose formulae for lactose-intolerant infants, while selected caseinates are used in the production of infant foods where a specific mineral balance is required, e.g., low sodium infant formulae for children with

338


specific renal problems. Casein hydrolysates are used in specialised foods for premature infants and in formulae for infants suffering from various intestinal disorders; casein hydrolysates, low in phenylalanine, have been proposed uses in formulae for feeding infants with phenylketonuria. The absence of Phe, Tyr, Trp and Cys residues in -casein glycomacropeptide make it a possible stable source of nutrition for phenylketonuria-sensitive patients. Casein products are added to various foods and drinks as a nutritional supplement. Caseins are used in special nutritional preparations for athletes as they enhance athletic performance which is attributed to the high glutamine levels that are important in the maintenance of muscle protein mass. Caseinates, co-precipitates and casein hydrolysates are often used in combination with whey protein concentrate or isolate in protein supplemented powders/beverages for athletes; calcium caseinate and micellar casein are used by athletes as a `slow release protein' supplement which decreases the rate of muscle degradation while dieting.21,257 Non-glycosylated caseinomacropeptide is used in weight reduction diet products (low carbohydrate yoghurts), where it stimulates the release of cholecystokinin, resulting in the production of insulin which inhibits gastric secretions that play an important role in controlling food intake and digestion in the duodenum of animals and humans.230 A casein-based diet containing high levels of TGF- (transforming growth factor beta) fed to children with Crohn's disease ameliorated chronic inflammation of the intestine.258 Whey protein enriched diets have been shown to reduce the growth of tumors in the GI tract, selectively inhibit cancer cell growth in head and neck cancer patients as well as aid the immune defence system against post-operative infections.177,178 Milk protein hydrolysates are used for intravenous nutrition for patients suffering from protein metabolism disorders, intestinal disorders, and for post-operative patients. Special casein preparations have been used as food for patients suffering from cancer, pancreatic disorders or anaemia. Biologically active peptides have shown potential applications in a wide variety of products; opiate peptides exhibit pharmacological properties similar to morphine while also influencing postprandial metabolism by stimulating pancreatic insulin and gastrointestinal somatisation release, prolonging gastrointestinal transit time and exerting antidiarrhoeal action.259±262 `BioZate', a whey protein isolate hydrolysate which contains an ACE-inhibitory peptide, has been shown to significantly reduce both systolic and diastolic blood pressure, as well as influencing immuno-defence systems and nervous system activity. This product exhibits both emulsifying and foaming properties, enabling this product to have a wide variety of applications including nutritional protein bars and beverages, meal replacers and specialised foods for sport nutrition. `Calpis'TM is a sour milk drink produced in Japan, and Èvolus', a calcium-enriched fermented milk drink produced in Finland, both contain antihypertensive peptides and have been shown to reduce blood pressure.263 Antibacterial peptides including Casocidin-I and Kappacin have a variety of applications in oral care products, due to their strong inhibition of gram-positive bacteria and gram-negative bacteria as well as showing an ability

Milk proteins 339 to bind to enterotoxins and inhibit viral and bacterial adhesions.234 Lactoferricin, which has antimicrobial and haemolytic activity, has been shown to be useful in the development of peptide antibiotics as therapeutic agents with low toxicity,191 and preparing medicines for treating acute gastritis, chronic gastritis, peptic ulcer and high stomach acidity.264 Casein derived peptides such as phosphopeptides, which have mineral binding ability have uses in the preparation of tablets, toothpaste and dental filling material.220 Sulphonated glycopeptides prepared from casein have been used for the treatment of gastric ulcers. Several other bioactive peptides may be used in pharmaceutical preparations, for example, casomorphins in the treatment of diarrhoea, casokinins (hypertension), casoplatelins (thrombosis) and immunopeptides (immuno-deficency).191 In the pharmaceutical industry, the oral route is considered the most convenient way of administering drugs to patients. Hydrophilic drugs cannot readily diffuse across the cells in the intestinal epithelium through the lipid bilayer. Milk proteins possess many of the properties required for effective drug delivery by oral administration as they are readily degraded at the low pH in the stomach and act as good microencapsulating agents. The ability of milk proteins to encapsulate a wide variety of materials suggests several promising applications in the food industry including use in the production of low calorie and reduced fat products, while masking off flavours, preventing oxidation and improving sensory characteristics; in the cosmetic industry to produce easily spreadable creams and lotions with encapsulated ingredients in both the oil and water phases and in the pharmaceutical industry to manufacture drug delivery systems.265 In the food industry, WPI or WPI/ lactose has been used to encapsulate anhydrous milk fat while also conferring good oxidative stability by preventing oxygen uptake.266 WPC may also be used in many applications as a fat replacer.267 Whey protein concentrate gels can be used as pH-sensitive hydrogels for controlled delivery of various materials including biologically active substances.268,269 Casein-dextran conjugates have been used as secondary emulsifiers in the preparation of multiple emulsions with the capability of encapsulating numerous materials (flavours, bioactive peptides and anticancer drugs) depending on their application, while also being safe for use in food, pharmaceutical and medical preparations. Multiple emulsions have been used to produce low caloric and flavoured mayonnaise.270 Semo et al.271 demonstrated that the casein micelle can be used as a nano-encapsulation vehicle for hydrophobic nutraceutical substances (vitamin D) for enrichment of non-fat or low-fat food products. 13.6.9 Convenience foods Applications of milk protein products in convenience foods are outlined in Table 13.15. Whey/caseinate blends are used as whitening agents in gravy mixes. Whey solids are included in dehydrated soup mixes and sauces to impart a dairy flavour, to enhance other flavours and to provide emulsifying and stabilising

340


Table 13.15

Application of not protein products in convenience foods


Effect/property

Sodium caseinate

Dry cream product for sauces, soups, nut substitute, imitation potato skin shells

Emulsification, nutrition, texture

Caseinate

Nut-like food Gravy mix

Film formation Whitening agent

Casein

Synthetic caviar

Texture

Hydrolysed casein

Whipping mixture

Whippability

Coprecipitate

Potato soup with rice, vegetable cutlets

Emulsification, nutrition, texture

WPC

Salad dressing, egg replacer Quiches, egg replacer Cream-based soups

Viscosity, mouthfeel, emulsification Cost, extender Cost

Whey solids Gravy mix, dehydrated soup mix

Whitener, flavour, emulsifier, stabiliser

effects. Caseinates are used as emulsifying agents and to control viscosity in canned cream soups and sauces and in the preparation of dry emulsions for use in dehydrated cream soups and sauces. Sauces and gravies containing whey proteins are reportedly less prone to cook-on to utensil walls, require minimum agitation and are stable to freeze-thaw cycling. Caseinate-whey protein blends are used as cheap replacements for skim milk powders in some convenience foods. Whey protein products may replace egg yolk in salad dressing and modified whey protein-based products potentially able to replace lipids in a variety of convenience foods have been developed. Milk protein products have been proposed as texture, stability and flavour enhancers in microwaveable foods. 13.6.10 Textured products Rewetted acid caseins or acidified rennet casein or co-precipitate, mixed with carbonates or bicarbonates of alkali metals or alkali earth metals, can be extruded to produce puffed snack foods while caseinates can be co-extruded with wheat flour to produce protein-enriched snack-type food products (Table 13.16). Fibrous meat-like structures can be formed from caseins, using fibre spinning techniques, and can be used as extenders in comminuted meats. If whey proteins are co-spun with the casein, fibres stronger than those containing casein alone are produced. Meat-like structure can also be formed from casein or coprecipitates by renneting followed by a combination of heat treatment and extrusion or working. Microwave heating of whey protein solutions results in

Milk proteins 341 Table 13.16

Application of milk protein products in textured products


Effect/property

Casein

Puffed food

Emulsification, texture, nutrition

Acid casein

Extruded milk protein product Foamed snack bar

Texture

Potassium caseinate

Fine bread, biscuits

Texture

Sodium caseinate

Sucroglyceride for baking

Texture, handling

Rennet casein

Dietary fibre snack

Texture

Coprecipitate

Dietary fibre snack

Texture

Whey protein Dietary fibre snack

Texture

WPC

Texture, cost

Surimi

simultaneous expansion and gelation to give textured products with potential for use in comminuted meats. WPCs are proposed as cost effective replacements for beef plasma protein or potato starch in the modification of surimi texture.272 13.6.11 Films and coatings Films formed from caseins/caseinates may be water soluble or water insoluble depending on the pH conditions used in their preparation, while the water vapour permeability of the film depends on the type of casein/caseinate used. Thermally induced disulphide crosslinking was found to be necessary when making films using WPCs and WPIs. The WPC-based films were excellent gas barriers, while the water vapour permeability of films could be reduced by incorporating lipids. Tensile strengths of the films were similar to synthetic films, and were enhanced by enzymatic polymerisation, e.g., transglutaminase. The films were generally flavourless, and transparent to translucent depending on protein source. Calcium-caseinate-based emulsions applied to fruit and vegetables were used to reduce moisture loss. The potential for the use of milk proteins in films and coatings in food applications has been discussed by Chen.273

13.7

Future trends

A large number of different milk protein products are presently recovered from milk and it is highly likely that this range will be further extended in the future. Cost effective commercial methods for separating individual casein and whey

342


protein fractions are currently emerging as new technologies are being developed and these fractions will become more widely available in the near future. Tailoring of milk protein products, most likely by enzymatic and physical modifications, will also be further developed to produce new speciality milk protein ingredients which meet the specific physico-chemical and functional demands of specific food applications. Commercial interest in milk protein hydrolysates and biologically active peptides is likely to continue to grow and to focus on procedures for the commercial preparation, isolation and purification of these products. A small number of milk protein derived biologically active peptides are presently commercially available; it is likely that the search for new milk-derived peptides will continue and an area of future focus will be the impact of interactions with other food constituents and technological processing procedures on their biological activity. While the main area of application for milk protein products will continue to be as functional ingredients in the food industry, the expanded range of milk protein-derived products will find increased uses in nutritional and nutraceutical applications. Consumer awareness of food ingredients will grow and consumers will view milk-derived protein and peptide ingredients as natural, wholesome, nutritious and healthy constituents in foods, thus enhancing and expanding their importance.

13.8

Sources of further information and advice

Further information regarding regulatory requirements for milk protein products (and milk products in general) may be obtained from the following: · American Dairy Products Institute, 300 West Washington Street, Suite 400, Chicago, Illinois, USA, Fax +13127825299. · USDA/AMS, Dairy Standardisation Branch, Room 2750- South Building, PO Box 96456, Washington, DC, USA. Fax +12027202643. · Food and Agriculture Organisation of the United Nations (Codex Alimentarius), Viale delle Terme di Caracalla, 00100-Rome, Italy. Fax +390657054593. · International Dairy Federation, 41, Square Vergote, 1030 Brussels, Belgium. Fax +3227330413. Information on milk protein products may be obtained from the following manufacturers and suppliers: · Armor Proteines, Le Pont, 35460 Saint Brice en Cogles, France. Fax + 33 2 99 97 7991. · Dairygold Food Ingredients, Clonmel Road, Mitchelstown, Co. Cork, Republic of Ireland. Fax + 353 (0) 25 44135. · Kerry Ingredients Ireland, Tralee Road, Listowel, Co. Kerry, Republic of Ireland. Fax + 353 (0) 68 21562.

Milk proteins 343 · Glanbia (formerly Avonmore-Waterford Group), Ballyragget, Co. Kilkenny Republic of Ireland. Fax + 353 (0)5688 36001. · Golden Vale Plc., Charleville, Co. Cork, Republic of Ireland. Fax + 353 (0) 63 35001. · Swiss Milk Company Ltd, 6281 Hochdorf, Switzerland. Fax + 41 41 910 1313. · DMV International, PO Box 13, 5460 BA, Veghel, The Netherlands. Fax + 31 413 362 656. · Carbery Food Ingredients, Ballineen, Co. Cork, Republic of Ireland. Fax + 353 (0) 23 47541. · Arla Food Ingredients, Head Office, Skanderborgvej 277, DK-8260, Viby J., Denmark. Fax + 45 8628 1838. · New Zealand Dairy Board, PO Box 417, Wellington, New Zealand. Fax + 64 4471 8600. · Century Foods International, PO Box 257, 919 Hoeschler Drive, Sparta, Wisconsin 54656, USA. Fax + 1 608 269 1910. · DENA GmbH, Villa Flora, Oberkasseler Street 26, D-40545, Dusseldorf, Germany. Fax +49211555583.

13.9 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.

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261. 262.

263. 264. 265. 266. 267. 268. 269. 270. 271. 272. 273. 274. 275.

14 Egg proteins M. Anton, INRA Nantes UniteÂ 1268 BiopolymeÁres Interactions Assemblages, France and F. Nau and V. Lechevalier, UMR INRA Science et Technologie du Lait et de l'Oeuf, France

Abstract: This chapter deals with the chemical composition and structural characteristics of egg yolk and white in relation to three important functional properties: emulsifying, foaming and gelling properties. Key words: egg, yolk, white, emulsions, foams, gels, structure, assemblies, interfaces.

14.1

Introduction: technofunctional uses of egg constituents

Hen egg was categorised by Baldwin in 1986 as a polyfunctional ingredient, as it can simultaneously realise several technological functions in the same formulated foodstuff. Its emulsifying, foaming, gelling, thickening, colouring and aromatic properties make it still today a universal basic ingredient for the domestic kitchen and the food processing industry. Whereas egg yolk is well recognised for its emulsifying properties, egg white (or albumen) is a reference in terms of foaming and both parts are used as gelling ingredient in many foods. Yolk takes part in the formation and the stabilisation of emulsions. In spite of the intensive use of yolk in formulated foodstuffs, and since the invention of mayonnaise three centuries ago, the role of its major constituents is not clear because of its complex structure. Yolk is a mixture of proteins and lipids forming natural assemblies at various scales. These natural assemblies contribute to the nano- and the microstructure of yolk. Thus, an understanding of the emulsifying properties of yolk lies in the comprehension of these various levels of structure.

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The exceptional foaming properties of the albumen are also the base of traditional recipes among which meringues act certainly as reference. Indeed, the extreme simplicity of their formula (albumen and sugar, possibly added with flavours) allows albumen to express in an optimal way its foaming properties. However, the technological parameters influence the final quality of foam obtained, and three types of meringues (traditional meringue, Swiss meringue and Italian meringue) can be distinguished, depending on whether whipping is achieved in the presence or absence of sugar, and at ambient or warm temperature. But there is also a great number of other products in which previously foamed albumen is added, which are either fat-free formulas (angel food cake) or lipid-containing formulas (spoon biscuits, `sponge' cake, blown). In such products, the complexity of the phenomena is extreme, foaming and emulsification taking place simultaneously, which makes the control of the physico-chemical and technological parameters of these operations very delicate. Concerning the gelling properties of albumen and yolk, they are related to the heat-gelation capacity of egg proteins. Then, these properties imply a cooking step during the food processing. The heat gelation of egg proteins completely conforms to the model of heat gelation of globular proteins. The corresponding mechanisms have been extensively studied, on egg proteins as well as on other ones, and the key technological parameters have now been identified. However, the addition of other ingredients in mixture with egg (polysaccharides, for example) complicates the understanding of the egg gelation behaviour, and developments with more complex models are still needed.

14.2

Physico-chemistry and structure of egg constituents

14.2.1 Egg yolk Chemical composition Yolk correspond to 36% of whole hen egg weight. Its dry matter is about 50± 52% according to the age of the laying hen and the duration of preservation (Kiosseoglou, 1989; Thapon and Bourgeois, 1994; Li-Chan et al., 1995). The compositions of fresh and dry yolks are presented in Table 14.1: the main components are lipids (about 65% of the dry matter) and the lipid to protein ratio is about 2:1. Yolk lipids are exclusively associated with lipoprotein assemblies. They are made up of 62% triglycerides, 33% phospholipids, and less than 5% cholesterol. Carotenoids represent less than 1% of yolk lipids, and give it its colour. Proteins are present as free proteins or apoproteins (included in lipoprotein assemblies). The interactions between lipids and proteins result in the formation of lipoproteins (low and high density), which represent the main constituents of yolk. Macrostructure and main constituents Yolk is a complex system with different structuration levels consisting in aggregates (granules) in suspension in a clear yellow fluid (plasma) that contains

Egg proteins 361 Table 14.1

Composition of hen egg yolk

Water Lipids Proteins Carbohydrates Minerals

Fresh yolk (%)

Dry yolk (%)

51.1 3.6 16.0 0.6 1.7

Ð 62.5 33.0 1.2 3.5

Source: Powrie and Nakai (1986)

lipoproteins and proteins. Granules consist in circular complexes ranging in diameter from 0.3 m to 2 m (Chang et al., 1977). Consequently, yolk can be easily separated into two fractions after a dilution (two times) with 0.3 M NaCl and a centrifugation at 10,000 g (30 min) according to the method of McBee and Cotterill (1979): a dark orange supernatant called plasma and a pale pellet called granules (Fig. 14.1). Granules represent 22% of yolk dry matter, accounting for about 50% of yolk proteins and 7% of yolk lipids. The dry matter content of granules is about 44%, with about 64% proteins, 31% lipids and 5% ash (Dyer-Hurdon and Nnanna,

Fig. 14.1 Fractionation of plasma and granules from hen egg yolk.

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Table 14.2

Repartition of hen egg yolk constituents Yolk D.M. (%)

Yolk lipids (%)

Yolk proteins (%)

Lipids (%)

Proteins (%)

100

100

100

64

32

Plasma LDL Livetins Others

78 66 10 2

93 61 Ð Ð

53 22 30 1

73 88 Ð Ð

25 10 96 90

Granules HDL Phosvitin LDLg

22 16 4 2

7 6 Ð 1

47 35 11 1

31 24 Ð 88

64 75 95 10

Yolk

Source: Powrie and Nakai (1986)

1993; Anton and Gandemer, 1997). They are mainly constituted by high density lipoproteins (HDL) (70%) and phosvitin (16%) linked by phosphocalcic bridges between the phosphate groups of their phosphoseryl residues (Burley and Cook, 1961; Saari et al., 1964). Low density lipoproteins (LDL) (12%) are included in the granular structure (Table 14.2). At low ionic strength, granules mainly form insoluble HDL-phosvitin complexes linked by phosphocalcic bridges as HDL and phosvitin contain a high proportion of phosphoserin amino acids able to bind calcium (Causeret et al., 1991). The numerous phosphocalcic bridges make the granule structure very compact, poorly hydrated, weakly accessible to enzymes, and lead to an efficient protection against thermal denaturation and heat gelation. At an ionic strength over 0.3 M NaCl, the phosphocalcic bridges are disrupted because monovalent sodium replaces divalent calcium. In such conditions, the solubility of granules reaches 80% because phosvitin is a soluble protein and HDL behave like soluble proteins (Cook and Martin, 1969; Anton and Gandemer, 1997). Complete disruption of granules occurs when ionic strength reaches 1.71 M NaCl. Acidification or alkalinisation similarly cause the disruption of granules and the solubilisation of these constituents by increasing the number of the positive (NH3+) or negative (COO-) charges inducing electrostatic repulsions between granule constituents. Recently, we have established (Sirvente, 2007) a phase diagram drawing the different states of granules as a function of pH and ionic strength (Fig. 14.2). Plasma comprises 78% of yolk dry matter and is composed of 85% LDL and 15% livetins (Burley and Cook, 1961; Table 14.2). It forms the aqueous phase where yolk particles are in suspension. It accounts for about 90% of yolk lipids (including nearly all the carotenoids), and 50% of yolk proteins. Plasma contains about 73% lipids, 25% proteins and 2% ash. Lipids of plasma are distributed thus: 70% triglycerides, 25% phospholipids and 5% cholesterol.

Egg proteins 363

Fig. 14.2 Physical state of granules as function of pH and ionic strength.

LDL are spherical particles (17±60 nm in diameter with a mean of about 35 nm) with a lipid core in a liquid state (triglycerides and cholesterol esters) surrounded by a monofilm of phospholipid and protein (Cook and Martin, 1969; Evans et al., 1973). LDL are soluble in aqueous solution (whatever the pH and ionic conditions) due to their low density (0.982). Phospholipids take an essential part in the stability of the LDL structure because association forces are essentially hydrophobic (Burley, 1975). Some cholesterol is included in the phospholipid film, increasing its rigidity. LDL are composed of 11±17% protein and 83±89% lipid, out of which 74% is neutral lipid and 26% phospholipid (Martin et al., 1964). 14.2.2 Egg white Egg white represents about 60% of the total egg weight. It consists of an aqueous protein solution, containing few minerals and carbohydrates (Table

364

Handbook of hydrocolloids Table 14.3 Composition of hen egg white % of hen egg white Water Lipids Proteins Carbohydrates Minerals

88.0 Ð 10.6 0.8 0.6

Source: Thapon and Bourgeois (1994)

14.3). During egg storage, different physico-chemical modifications happen, among them the CO2 departure that induces a pH increase, from 7.5 at the laying moment to 9.5 after a few days. This pH modification should be the cause of the egg white liquefaction, because of the dissociation of a protein complex (ovomucin-lysozyme complex) (Kato et al., 1975). Another evolution observed concerns the ovalbumin modification toward S-ovalbumin, which is a more heat-stable form (Smith and Back, 1965), resulting from isomerisation of three serine residues (Yamasaki et al., 2003). Proteins Proteins represent more than 90% of the dry matter of egg white, but until very recently, only the major ones have been identified. However, the recent and powerful techniques for separation and analysis enabled the identification of many minor proteins (Table 14.4) (GueÂrin-Dubiard et al., 2006; Mann, 2007). The egg white proteins are predominantly globular proteins, and acidic or neutral, except lysozyme and avidin which are highly alkaline proteins. All are glycosylated, except cystatin and the major form of lysozyme. Some of them are very heat-sensitive and/or sensitive to surface denaturation, explaining their noteworthy functional properties. The major egg white protein (more than 50% of the total proteins) is ovalbumin, a 45 kDa globular and phosphorylated protein. Half of its amino acids are hydrophobic, and one-third are electrically charged, essentially negatively at physiologic pH. Ovalbumin possess six buried Cys residues, two being involved in a disulfide bridge (Cys73-Cys120). Ovalbumin is then the only egg white protein with free thiol groups, capable of inducing some rearrangements with variations of storage conditions, pH and surface denaturation. Ovotransferrin (13% of total proteins) molecular weight is around 78 kDa. This protein consists of two lobes, each containing a specific binding site for iron (or copper, zinc, aluminium) (Kurakawa et al., 1995). It is the most heatsensitive egg white protein, but the complexation of iron or aluminium significantly increases its heat stability (Lin et al., 1994). OvomucoõÈde is a highly glycosylated protein (up to 25% carbohydrates, w/w) of 28 kDa. At pH 7, its denaturation temperature is around 77 ëC, but this protein

Egg proteins 365 Table 14.4 Composition and some physico-chemical and functional properties of egg white proteins %

Mw (kDa)

pI

Ovalbumin Ovalbumin Y Ovalbumin X Ovotransferrin OvomucoõÈd Ovomucin

54 5 0.5 13 11 1.5±3.5

45 44 56 76 28 230±8300

5 5.2 6.5 6.7 4.8 4.5±5

Lysozyme Ovoinhibitor Ovoglycoprotein Flavoprotein Ovostatin Cystatin Avidin Ex-FABP Cal gamma TENP

3.5 0.1±1.5 0.5±1 0.8 0.5 0.05 0.05 nd nd nd

14.4 49 24.4 32 760±900 12.7 68.3 18 20.8 47.4

10.7 5.1 3.9 4 4.6 5.1 10 5.5 6 5.6

nd

18

6.4

Protein

Hep 21

Major biological properties Immunogenic phosphoproteine nd nd Iron binding, bacteriostatic activity Trypsin inhibitor Highly glycosylated, viral hemaglutination inhibition Lysis of Gram bacteria wall Serine protease inhibitor nd Riboflavin (vitamin B2) binding Serine protease inhibitor Cysteine protease inhibitor Biotine binding Lipocaline family Lipocaline family BPI (bactericidal permeabilityincreasing protein) family uPar/Ly6/Snake neurotoxin family

Sources: Li-Chan and Nakai (1989), Stevens (1991), GueÂrin et al. (2006).

is much more heat resistant at acidic pH (Lineweaver and Murray, 1947). Ovomucin is also a highly glycosylated protein, with a very high molecular weight (104 kDa). Electrostatic interactions can be observed between ovomucin and some of the other egg white proteins. In the freshly laid eggs (pH 7.5), the carboxylic groups of the ovomucin sialic acids especially interacts with the NH3+ of lysozyme lysine residues to form a lysozyme-ovomucin complex that may be responsible for the gel-like structure of egg white (Kato et al., 1975). Lysozyme is a small (14 kDa) globular, and strongly basic protein. Its structure is very rigid, stabilised by four disulfide bridges. Glucidic and mineral fractions The glucidic fraction of egg white consists of free glucose (0.5% w/w) and carbohydrates linked to proteins (0.5% w/w). The mineral fraction is predominantly composed of Na+, K+ and Clÿ, as free minerals, whereas P and S are essentially constitutive elements of proteins. Egg white also contains CO2, in equilibrium with bicarbonate, which plays a major role for pH control (Thapon, 1994).

14.3

Egg yolk emulsions

14.3.1 Basic principles Emulsifying activity is related to the capacity of surface active molecules to cover the oil±water interface created by mechanical homogenisation, thus

366


reducing the interfacial tension. Consequently, the more active the emulsifying agent, the more the interfacial tension is lowered. Emulsion stability indicates the capacity to avoid flocculation, creaming, and/or coalescence of oil droplets. Creaming and flocculation are reversible phenomena which can be avoided by a simple agitation of the emulsion. Coalescence is the irreversible fusion of oil droplets due to the rupture of the interfacial film created by emulsifying agents. This phenomenon leads to a complete destruction of the emulsion. This relates the importance of the structure and the viscoelasticity of the interfacial film. 14.3.2 Role of egg yolk constituents In researching the principal contributor to yolk emulsifying properties, numerous authors have separated yolk into its main fractions: plasma and granules. Large similarities have been observed between emulsifying properties of yolk and plasma, whereas emulsions made with granules behaved very differently (Dyer-Hurdon and Nnanna, 1993; Anton and Gandemer, 1997; Le Denmat et al., 2000). Specifically, emulsions made with granules are more coarse (more important oil droplet size) than emulsions made with yolk and plasma, and notably at acidic pH where granules are not soluble (Le Denmat et al., 2000) (Fig. 14.3). Concerning the parameters of emulsion stability (creaming), we showed (Le Denmat et al., 2000) that emulsions made with yolk and plasma had the same creaming rate, in function of the medium conditions, whereas emulsions made with granules behaved very differently (Fig. 14.3). Consequently, these studies demonstrated that yolk emulsifying power was situated in plasma. Among plasma constituents, some authors demonstrated that LDL are better emulsifiers than bovine serum albumin (BSA) (Mizutani and Nakamura, 1984) and casein (Shenton, 1979). Even though some authors suggested that, in certain conditions, HDL were more efficient than LDL to form and stabilise O/W emulsions (Hatta et al., 1997; Mine, 1998), a large number of studies confirm the prevalent role of LDL in yolk emulsions. These findings have been confirmed recently (Aluko et al., 1998; Mine and Keeratiurai, 2000; Anton et al., 2003; Martinet et al., 2003). In particular, it has been established that LDL made emulsions finer than HDL, along different conditions of pH and ionic strength (Martinet et al., 2003). The next question is how to explain the exceptional efficiency of LDL at the interfaces. 14.3.3 Importance of assemblies Given that any destructurating treatment affects the emulsifying properties of LDL, it appears that the integrity of the structure of LDL seems essential to ensure their interfacial properties (Tsutsui, 1988). Direct adsorption of apoproteins and phospholipids from LDL is not easy because of the nonsolubility of these species in water or in aqueous buffer. So the interactions between apoproteins and lipids to assemble the LDL particles are essential to

Egg proteins 367

Fig. 14.3 Mean droplet diameter (d3.2) and creaming index (Icr) in oil/water emulsions (30 : 70) prepared with yolk, plasma and granules, protein concentration: 25 mg/ml, homogenisation pressure: 200 bars, n 3.

368


Fig. 14.4 /A isotherms of the different lipid constituents extracted from LDL and spread at the air±water interface; neutral lipids = 85 g, phospholipids = 198 g, total lipids = 287 g, compression rate = 100 cm2/min.

transport the surfactants in a soluble form in the neighbourhood of the interface and then to release them at the interface. Using Langmuir film balance (air±water interface), three phase transitions have been detected in compression isotherms and these three transitions (19, 41 and 54 mN/m) have been attributed, respectively, to neutral lipids, apoproteins and phospholipids by comparison with films of neutral lipids, phospholipids and total lipids extracted from LDL (Fig. 14.4) (Martinet et al., 2003). The transition observed at 19 mN/m corresponds to the collapse of neutral lipids, and the transition at 54 mN/m corresponds to phospholipid collapse. These different transitions show that LDL actually break down when they come into contact with the interface to release neutral lipids, phospholipids and apoproteins from the lipoprotein core and to allow their spreading. In a recent study made with atomic force microscopy (AFM) after a Langmuir±Blodgett transfer of the layers from the air±water interface to a silica plate, it has been shown that the second transition (previously attributed to apoproteins alone) is not due to apoproteins alone, but to apoprotein±lipids complexes (Dauphas et al., 2006). So, it has been deduced that LDL serve as vectors of surfactant constituents (apoproteins and phospholipids) that could not be soluble in water, until the interface. At this step the conservation of the LDL structure is essential. Once LDL are near the interface, the structure is then broken up to release surfactant constituents at the interface (Fig. 14.5). Furthermore, comparing interfacial behaviour of LDL and liposomes (double phospholipid layer not containing proteins), it has been shown that the apoproteins situated on the LDL surface start the LDL disruption mechanism by

Egg proteins 369

Fig. 14.5 Hypothetical mechanism of LDL adsorption at an oil±water interface as compared with liposome behaviour.

their initial anchorage. This anchorage provokes an unfolding of the protein leading to the destabilisation of the external layer of the LDL. Then this phenomenon could be followed by a deformation of the particle due to the creation of a neutral lipid lens conducive to the spreading of the LDL constituents. In the case of liposomes, without external proteins, the structure remains steady at the interface and then this structure is not able to adsorb efficiently and to decrease interfacial tension (Fig. 14.5).

14.4

Egg white foams

14.4.1 Formation and stabilisation mechanisms Foam formation is a highly energetic and dynamic process, in which interfacial area is created. The ability of a protein solution, such as egg white, to foam depends on protein structure and conformation, depending themselves on extrinsic factors such as pH, ionic strength, etc. The formation mechanism of globular protein foams can be divided into three phases happening near gas bubbles: protein diffusion towards the air±solution interface, conformation changes of adsorbed proteins, and irreversible rearrangement of the protein film (McRitchie, 1991). Foams are short-lived states and there is any correlation between foam stability and protein adsorption kinetic (Dickinson, 1996). Foam stability, indeed, depends on protein association at the air±solution interface to form a

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continuous intermolecular network. Foam stability is affected by the protein film cohesion, drainage and Ostwald disproportionation. 14.4.2 Interfacial properties of egg white proteins Interfacial properties of egg white proteins are responsible for egg white's excellent foaming properties. Table 14.5 gathers some data on the kinetics of diffusion towards the air±solution interface of three major egg white proteins. Ovalbumin interfacial behaviour is well known, since a large set of data is available about its tensioactivity, adsorption kinetics, interfacial shear and dilatational rheology (de Feijter et al., 1978; de Feijter and Benjamins, 1987; Benjamins and van Voorst Vader, 1992; Benjamins and Lucassen-Reynders, 1998; Damodaran et al., 1998; Lucassen-Reynders and Benjamins, 1999; Pezennec et al.; 2000; Razumovsky and Damodaran, 2001; Croguennec et al., 2007) but also on its structure at the air±water interface (Renault et al., 2002; Lechevalier et al., 2003, 2005; Kudryashova et al., 2003). It is now known that ovalbumin forms a single layer at the air±water interface, whatever its concentration in the bulk (Renault et al., 2002). As for ovalbumin, lysozyme interfacial behaviour has been extensively studied (de Feijter and Benjamins, 1987; Damodaran et al., 1998; Razumovsky and Damodaran, 2001; Kim et al., 2002; Postel et al., 2003; Chang et al., 2005; Roberts et al., 2005; Perriman and White, 2006) as well as its structure at the air±water interface (Lechevalier et al., 2003, 2005). However, its interfacial behaviour differs as lysozyme forms films that are much thicker than a protein monolayer whereas the surface pressure is definitely smaller than the ovalbumin one (Le Floch-FoueÂreÂ et al., 2009). These different behaviours observed on planed air±water interface result in different foaming properties. Ovalbumin foaming properties are much better than those of lysozyme, since in native state at pH 7.0, the foaming capacity of lysozyme is very weak (Townsend and Nakai, 1983), probably because of its little surface hydrophobicity and its rigidity due to its four disulfide bonds. Egg white proteins thus show different behaviour at 2D and 3D air±water interfaces. When they are in mixture, their behaviour is again different. Indeed, Damodaran et al. (1998) showed that the adsorption kinetics of egg white proteins are different depending on whether they are in single protein systems or in mixture. They suggested the formation of electrostatic complexes between positively charged lysozyme and other negatively charged egg white proteins. Moreover, the mixture ovalbumin-lysozyme forms films that are much thicker than those of both proteins in single protein systems, suggesting a synergy in interfacial adsorption between the two proteins (Le Floch-FoueÂreÂ et al., 2007). 14.4.3 Egg white foams Egg white is the reference for foaming properties: compared with other protein ingredient of vegetable or animal origin, it still offers the best foaming properties (Vani and Zayas, 1995; Matringe et al., 1999; Pernell et al., 2002;

Table 14.5 Parameters of the kinetic of diffusion towards the air±solution interface of three major egg white proteins Parameters

Ovalbumin

Apparent diffusion coefficient (10ÿ10 m2 sÿ1)

0.5 (C=10ÿ4% prot.) (in solution: 0.7)

Surface concentration (mg mÿ2)

Surface pressure (mN mÿ1)

Lag phase

Ovotransferrine

0.5 to 1 (C=0.1% prot.) 1.6 (C=10ÿ4% prot.) 1.5 (C=5.410ÿ4% prot.) 2.1 (native protein) to 2.9 (heat-treated protein) (C=0.01% prot.)

0.8 (C=1.210ÿ4% prot.)

1 (C=10ÿ4% prot.) 14 (C=5.410ÿ4% prot.) 24 (C=0.01% prot.)

YES if C 20 mM) effects during the electrostatic complexation between BSA and pectin at the surface of a quartz crystal microbalance. Such a salt content dependency of complex formation was also described for purely cognate protein±polysaccharide systems (Moss et al. 1997). Hence, it was shown that cartilage lysozyme/chondroitin sulfate complex formation under physiological pH was suppressed in presence of 140 mM NaCl, whereas only 60 mM were sufficient to prevent complex formation between the same protein and hyaluronan. The authors explained that this specific salt dependence of complex formation was at the origin of the ability for mammalian lysozyme to dissociate proteoglycan assemblies in the cartilage. Some studies have considered the interplay between the ionic strength and the critical pHc and pH. The general trend is that for a given protein to polysaccharide ratio, both pH values are generally shifted towards more acidic values in order to compensate the partial screening of the charges induced by the added microions (GrymonpreÂ et al. 2001), i.e., the charge density of proteins needs to be increased so as to reach the same level of charge neutralization between proteins and polysaccharides. For example, pH decreased from 9 to 7 upon addition of 200 mM NaCl in the gelatine/-carrageenan system at a protein to polysaccharide weight ratio of 1:1 (Fang et al. 2006) or from 4.75 to 4.25 in whey proteins/acacia gum mixture at a ratio of 2:1 (Weinbreck et al. 2003b). To conclude this section, it is worth mentioning the very interesting results reported by Weinbreck et al. (2004b) on the importance of the type of ions

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present in the mixture upon control of ionic strength in the whey proteins/carrageenan system. It was shown that addition of sodium chloride was shifting the pH to more acidic pH, as reported for other systems. However, when calcium chloride was used, a marked shift of pH towards more basic pH values (up to pH 8 upon addition of 200 mM CaCl2) could be observed. The given explanation was that the two negatively charged biopolymers were indirectly forming complexes via calcium bridges. Thus, ionic strength dependence for complex formation between protein and polysaccharide might not only be related to salt concentration, but sometimes to the type of ion. After having considered the pH and ionic strength, the two major parameters affecting directly the number of charges on the macromolecules, we will now discuss the effects of mixing ratio that is modifying the balance between the charges at constant pH and ionic strength. Influence of protein to polysaccharide weight ratio Electrostatic complex formation and coacervation can be maximized for a given set of pH and ionic strength conditions when the optimum protein to polysaccharide mixing ratio (Pr:Ps) is found. This experimental evidence has been modelled for a globular protein±flexible polyelectrolyte system using Monte Carlo simulation and it was found that these conditions exactly corresponded to full charge compensation between the two macromolecules (Akinchina and Linse 2002). The optimum ratio can be determined from electrophoretic mobility measurements of the two biopolymers at constant weight concentration or by measuring the turbidity and scattered light intensity of mixtures upon titration (Burgess and Singh 1993; Xia and Dubin 1994; Bowman et al. 1997; Schmitt et al. 1999; Ye et al. 2006). At the complete charge neutralization ratio, the electrophoretic mobility of the complexes converges to zero, whereas the turbidity or scattered light intensity passes through a maximum indicating a maximum mass within the electrostatic complexes and/or a maximum number of formed particles. For protein to polysaccharide ratios below the neutralization point, complexes remained soluble because of insufficient charge neutralization. Interestingly, this was generally traduced by a steady state for the size of the complexes, while the scattered light intensity was still increasing as was reported by Weinbreck et al. (2003b) during whey proteins±acacia gum complex formation. The latter result clearly indicated that before phase separation occurred, an increasing number of similarly sized complexes were formed. Regarding the interplay between the protein to polysaccharide ratio and the two critical pH values, pHc and pH, it is important to note that pHc is independent from the mixing ratio (Mattison et al. 1995; Kaibara et al. 2000). Thus, as soon as protein molecules mix with the polysaccharide ones, soluble complexes start forming, independently from the initial mixing ratio. In contrast, the critical pH value leading to phase separation, pH, is strongly ratio dependent as it corresponds to full charge neutralization of the complexes, or in other words, full saturation of the polysaccharide chains by protein molecules (Kaibara et al. 2000).

Protein±polysaccharide complexes and coacervates

435

Another important external parameter influencing complex formation and coacervation is the total biopolymer concentration. Influence of total biopolymer concentration Veis et al. (1967) already took this parameter into account in their model. They assumed that once the biopolymer concentration was higher than a critical value, the energetic entropic advantage of forming electrostatic complexes to release counterions disappeared as counterions would be as concentrated in the dilute and in the coacervate phase. This would be the main reason why experimentally, the two-phase region is defined by a finite area in ternary phase diagrams and why complex coacervation can be induced from a monophasic system upon dilution with the solvent (Phares and Sperandio 1964). From the extensive study of a series of protein±polysaccharide complexes, Tolstoguzov (1986) concluded that suppression of coacervation occurred around a total biopolymer concentration of 4 wt%. In fact, it seems that this critical concentration is highly system dependent as, for example, a critical concentration of 4.5 wt% was needed to observe self-suppression of coacervation in the -lg/acacia gum system at pH 4.2 (Schmitt et al. 2000). Very interestingly, the presence of protein aggregates in the same system induced an increase of the selfsuppression concentration from 4.5 wt% up to 20 wt%, suggesting that a control of coacervation self-suppression could be obtained tailoring the size and surface properties of aggregates (Schmitt et al. 2000). In a very close system, whey proteins/acacia gum, but a pH 3.5, it was reported that complexes could be observed up to 15 wt% (Weinbreck et al. 2003b). The likely reason to explain these experimental differences was that the electrostatic entropy gain at pH 3.5 was still advantageous at 15 wt%, but not more around 4.5 wt% at pH 4.2. To conclude on the importance of the total biopolymer concentration, it is worth mentioning that it has been reported to have no effect on pHc or pH for total biopolymer concentrations below 0.5 wt% (Mattison et al. 1995, 1999; Weinbreck et al. 2003b, 2003c). Nevertheless, for higher biopolymer concentration, pH has been reported to shift to higher values as was the case in the whey proteins/acacia gum system (Weinbreck et al. 2003b). Finally, the size of the coacervates was shown to depend on the total biopolymer concentration up to 1 wt% for the -lg/acacia gum system at pH 4.2 (Schmitt et al. 2000). For higher concentration, the coacervate size remained independent of total biopolymer concentration, showing again the importance of the concentration range tested to observe or not effects. Apart from the chemical parameters described above, several physical parameters, such as the temperature, the pressure or the shearing, might influence the formation of protein±polysaccharide complexes or coacervates. Influence of temperature, shearing and pressure Temperature is known to possibly affect conformation of proteins and polysaccharides, but also to favour several non-electrostatic interactions (Tolstoguzov 1997; Schmitt et al. 1998). Low temperature is, in principle,

436


Fig. 16.3 Evolution of the binding enthalpy (H) with temperature during the titration of an aqueous dispersion of total acacia gum (1.8 wt%) into an aqueous dispersion of -lg (0.6 wt%) at pH 4.2. Line corresponds to a linear fit of data. The slope represents the heat capacity changes (C p).

favourable to hydrogen bonding whereas higher temperature is favourable to hydrophobic interactions. For example, it can be seen in Fig. 16.3 that the binding enthalpy recorded in the -lg/acacia gum system decreased (became less negative) with increasing temperature. The molar heat capacity, Cp , calculated from the slope of the H vs. temperature relationship, originated from changes in the degree of surface hydration in the free and complexed molecules, and to a lesser extent from changes in molecular vibrations (Jelesarov and Bosshard 1999). The Cp calculated from Fig. 16.3 was large and positive, a typical signature of ionization/charge neutralization reactions (Ziegler and Seelig 2004; GoncËalves et al. 2005; Chung et al. 2007). A positive Cp but with a H parameter remaining favourable at all temperatures studied, i.e. H < 0, would be indicative of a significant contribution of hydrogen bonding (GoncËalves et al. 2005). The importance of hydrophobic interactions in other protein± polysaccharide systems has been shown. In some cases electrostatic binding between macromolecules was impossible unless strong hydrophobic interactions are generated by heating (Zhang et al. 2007). Other interesting results highlighted the effect of temperature on the conformational changes in BSA and the resulting formation of complexes with alginate (Harding et al. 1993). Thus, between 35 and 70 ëC, no complexes were formed at pH 6.8 at an ionic strength of 0.1 M, whereas complexes appeared above 70 ëC. Complex formation was mainly related to the conformational changes of BSA around its denaturation temperature of 55 ëC, so that additional


437

hydrophobic groups could be exposed, favouring complex formation. Similar effects of temperature have been reported upon complex building between gelatine and -carrageenan (Fang et al. 2006). Temperature values above the conformational transition of both biopolymers, i.e. > 25 ëC led to complex coacervation, whereas thermodynamic incompatibility occurred below 25 ëC. In a very recent study involving complex formation between two proteins, -la and lysozyme, it was shown that below 5 ëC, precipitates were obtained whereas coacervates were formed if the mixing temperature was 45 ëC (Nigen et al. 2007). This change in the nature of the solubility of the formed complexes was due to a conformational change of the -la at temperatures higher than 27 ëC, enabling adoption of a molten-globule conformational state that was favouring exposure of hydrophobic regions. This study suggested that electrostatic interactions could be mostly important during the initial biopolymer complex formation but large-scale aggregation or coacervation would be mainly driven by hydrogen bonding or hydrophobic interactions, depending on the temperature. In a very recent paper, it was shown that temperature could also affect the structure of the polysaccharide (Kayitmazer et al. 2007). Hence, the effect of temperature (12 or 25 ëC) on the structure of BSA/chitosan was compared to BSA/poly(diallyldimethylammonium chloride) (PDADMAC). It was shown, that even if the two polyelectrolytes had very similar charge densities, different rheological properties were obtained for the coacervate phase, probably due to the fact that temperature had a stronger effect on the flexibility of chitosan, but not on that of PDADMAC. Several studies were related to the effect of temperature on pHc and pH, leading to the conclusion that these critical pH values were not affected as long as electrostatic interactions were mainly involved in the complex formation mechanism (Kaibara et al. 2000; Weinbreck et al. 2004b; Singh et al. 2007). Another possibility to control the formation of protein±polysaccharide complexes is to apply pressure to the system in order to partially denature proteins. For example, Galazka et al. (1999b) reported the formation of ovalbumin/ dextran sulfate electrostatic complexes at low ionic strength and pH 6.5 after high-pressure treatment of the mixture at 600 mPa for 20 minutes. This type of weak electrostatic complex formation upon high pressure treatment was also highlighted when ovalbumin was mixed with -carrageenan. Another important physical parameter influencing more generally the coacervation phenomenon rather than the complexation one is shearing. Most of the studies reported results carried out in non-controlled shearing devices; however, some trends could be discerned. When protein±polysaccharide mixtures were submitted to mixing (below 1000 rpm), the size of the coacervates was generally decreasing with the increase of the shearing rate (Elgindy and Elegakey 1981; Burgess and Carless 1985; Tirkkonen et al. 1994; Ovez et al. 1997; Sanchez et al. 2001). The given explanation was mainly a breakdown of the coavervates due to interfacial destabilization by the shear, as is the case for emulsions, leading to fragmentation of the coacervate phase into smaller

438


droplets. For higher mixing rates (3500 rpm), an increase of the coacervate size was reported, probably because complex turbulent flow was favouring recoalescence of the coacervates (Sanchez et al. 2001). Interestingly, an additional effect of the time of shearing was noticed for low shearing rates (below 1000 rpm), as an increase of the coacervate size was demonstrated for constant shearing rate in the case of gelatine/gelatine (Burgess and Carless 1985), -lg/ acacia gum coacervation (Schmitt et al. 1998) or gelatine/chitosan (RemunanLopez and Bodmeier 1996). In these experiments, the shearing applied was likely favouring coalescence of the coacervates or not high enough to prevent it. Two additional internal parameters have been shown to control protein± polysaccharide complex formation, the charge density and the molecular weight of the biopolymers. 16.3.2 Internal parameters Influence of biopolymer charge density The charge density of the biopolymer is defined by the number of charges present for a given distance along the protein or polysaccharide chain. The charge density is of great importance in the type of phase separation obtained in protein±polysaccharide complexes as high charge density (sulphate or phosphate side chains) generally led to precipitates, whereas lower charge densities (carboxylic side chains) led to liquid coacervates (Frugier and Audebert 1994; Weinbreck et al. 2003b, 2003c, 2004b). This effect was attributed mainly to the fact that strong electrostatic interactions induced high compaction of the complexes with a high level of local dehydration of the biopolymer chains, leading to insolubilization in the form of precipitates. Interestingly, high charge density allowed the formation of soluble complexes on a larger range of ionic strengths due to the local strong electrostatic interactions that were able to overcome the screening effects induced by microions (Mattison et al. 1998; Y. Wang et al. 2000). For a given type of side groups, the charge density could lead or not to the formation of complexes as was shown in mixtures of ovalbumin with carrageenans or dextran sulphate at pH 6.5, i.e., above the IEP of the protein (Galazka et al. 1999b). Hence, formation of electrostatic complexes was shown to be possible on the `wrong' side of the IEP of the protein, i.e. when both biopolymers carry opposite charges (Park et al. 1992; Mattison et al. 1998). Such local high charge density regions were named `charges patches'. These patches can be generated on synthetic polyelectrolytes but they can already exist on proteins (de Vries et al. 2003). For example, sequence analysis of the charge distribution on the surface of -lg and -la led to the conclusion that -la could bind electrostatically to acacia gum through a single patch, whereas binding of acacia gum to -lg occurred via several patches (de Vries 2003). This could explain why -la was able to form electrostatic complexes more than one pH unit higher than its IEP (Weinbreck and de Kruif 2003). Such a type of single electrostatic patch has also been described on the surface of human serum


439

albumin, allowing complex formation with hyaluronic acid (GrymonpreÂ et al. 2001). Another way to describe this phenomenon is that ion±dipole interaction overcomes ion±ion repulsion. However, another possible explanation would be that when the polyacid/polybase is strong enough or the protein has a high enough regulation capacity, a reversal of charge may be induced on the protein (Bisheuvel and Cohen Stuart 2004). The capacitance is an intrinsic property of a protein defining its ability for charge regulation, i.e., to change their charges upon interaction with a polyelectrolyte. It was shown recently by Monte Carlo simulations and perturbation theory that -la, -lg and lysozyme displayed very strong capacitance at and near their IEP (da Silva et al. 2006). This induces an additional and strong attraction of several kT between proteins and polyelectrolytes through charge-induced charge interactions. A last internal parameter that is closely related to the biopolymer charge density is the molecular weight, which also plays an important role on the resulting biopolymer flexibility (Kayitmazer et al. 2005; Cooper et al. 2006). Influence of biopolymer molecular weight The increase of the molecular weight of the polyelectrolyte or polysaccharide was shown to favour the formation of electrostatic complexes (Zaitzev et al. 1992; Semenova 1996). The understanding of these observations was that the volume occupied by the polyelectrolyte increased with its molecular weight, enabling a higher number of proteins to interact with it and to build complexes. Here, a very interesting effect of the polyelectrolyte and the charge density was shown when polyacrylic acid was mixed with lysozyme or ovalbumin (Shieh and Glatz 1994). No effect of the increase of the molecular weight of the polyacrylic acid was observed with lysozyme, as both polymers had close charge densities. However, a much stronger binding of ovalbumin was detected when increasing the molecular weight of the polyacrylic acid, due to the larger difference in charge density. Y. Wang et al. (2000) tested coacervation between anionic surfactant micelles and PDADMAC of various molecular weights. They came to the conclusion that a critical molecular weight of the polycation existed for every total polymer concentration and mixing ratio tested. This critical molecular weight was leading to a critical size of 45 nm for the complexes, enabling coacervation to occur. Recently, Laneuville et al. (2005b) reported the influence of the molecular weight of xanthan gum on the size and compactness (fractal dimension, df) of the formed electrostatic complexes. With low molecular weight xanthan gum, smaller complexes with high df (2.56, i.e. compact) were obtained, whereas much larger and more linear complexes (df 2.26) were obtained with the high molecular weight xanthan gum. It is worth noting that several studies have been undertaken on the modelling of the effect of polyelectrolyte molecular weight on the formation of soluble complexes or coacervates (SkepoÈ and Linse 2003; Akinchina and Linse 2003). The main conclusion was that small molecular weight polyelectrolytes generally led to soluble complexes, whereas larger ones induced further aggregation of the soluble complexes leading ultimately to

440


complex coacervation. These simulations fitted reasonably with the experiments described above for real systems. After having reviewed the most important parameters controlling the formation of protein±polysaccharide complexes and coacervates, we now turn to understanding their structure formation and morphology.

16.4 Structure, morphology and coarsening of protein± polysaccharide complexes and coacervates The understanding of the structure of protein±polysaccharide complexes and coacervate structure from the molecular to the macroscopic level is probably the topic that has received the most scientific interest during the last decade (Schmitt et al. 1998; Turgeon et al. 2007). 16.4.1 Molecular level Regarding the molecular structure of the protein and the polysaccharide in the complexes and coacervate, most of the information was gained from the use of calorimetry and spectroscopy. For example, Imeson et al. (1977) reported that the denaturation temperature of BSA or myoglobin was increased upon mixing with anionic polyelectrolytes, and concluded that complexes were formed, leading to increased protein heat stability. In another study, the content of helix structure of ribulose diphosphate carboxylase was followed by circular dichroism upon complexation with pectins close to the IEP of the protein (Braudo and Antonov 1993). It was shown that complex formation was leading to a loss of -helix in the protein, enabling identification of which regions of the protein were involved in the interaction. This loss of -helix structure was also reported upon complexation of -lg with acacia gum, especially close to the EEP (Schmitt et al. 2001a; Mekhloufi et al. 2005). The likely explanation for this observation was that this region of the protein was rich in positively charged amino acids at the given pH, but also that these amino acid residues were exposed to the solvent at the surface of the protein. The same -helical region with high charge density of -lg was identified in the interaction with pectin (Girard et al. 2003a). In addition, a loss of helical structure was also reported upon complex formation between lysozyme and polystyrene sulfonate by means of Fourier transform infrared spectroscopy (Cousin et al. 2005). Nevertheless, depending on the structure of the protein, complex formation may also lead to an increase in -helix as, for example, upon complex formation between poly(Llysine) and -carrageenan (Girod et al. 2004). In the same vein, helical regions of -gliadin proteins were mainly involved in the complex formation with gum arabic, whereas -sheets were involved when pea globulin protein was tested (Chourpa et al. 2006). In another study dealing with complex formation/ coacervation processes in -lg/acacia gum system, a loss in the amount of helix protein structure after complexation and a gain in protein secondary


441

structure after complex formation were shown (Mekhloufi et al. 2005). By contrast, Delben and Stefancich (1998) reported no structural changes upon complex formation between ovalbumin and glutamate glucan, which might be due to the compact structure of this protein. It seems obvious that no generalization can be drawn from these different results since both protein conformational changes and unchanged states are described in the literature. Interestingly, not only could the molecular structure of the protein be modified upon complex formation, but also that of the polysaccharide. For example, the helical structure of - and -carrageenans was shown to be completely lost upon interaction with -casein as more protein was bound to the polysaccharide chain (Burova et al. 2007). This was an indication that the electrostatic interactions between the two biopolymers were preventing the formation of the secondary hydrogen bonds that are responsible for the helical structure of the bare polysaccharide. Also conformational changes affecting a potassium pectate upon complexing with two enantiomeric forms of poly(lysine) were studied (Paradossi et al. 2001). The pectate adopts a super-helical conformation around the -helix of the poly(L-lysine) but not with poly(Dlysine), indicating a stereo-specificity of the interaction of poly(lysine) with pectate. 16.4.2 Mesoscopic level This structural level is related to the soluble complexes or soluble complex aggregates arising from the charge neutralization of the two biopolymers. Here, it should be mentioned that a number of experimental data have been reported on protein±polyelectrolyte systems, but that still scarce data are available on protein±polysaccharide complexes (Turgeon et al. 2003). However, interesting molecular simulations carried out on model polyelectrolytes/macroions complexes with different chain length, flexibility, charge or mixing ratio led to several possible structures ranging from linear to globular complexes (de Vries and Cohen-Stuart 2006; Ulrich et al. 2006). In terms of size, hydrodynamic diameters reported from light scattering experiments on various protein/ polysaccharide systems varied between 100 and 300 nm (GrymonpreÂ et al. 2001; Weinbreck et al. 2003b; Mekhloufi et al. 2005; Schmitt et al. 2005b). An example of aggregated complexes based on the interaction between -lg and acacia gum is shown in Fig. 16.4. An interesting feature related to the structure of the electrostatic complexes close to the EEP was that the polydispersity index measure by light scattering was very low (i.e. below 0.1), indicating a very homogeneous composition of all the complexes before macroscopic phase separation (Mekhloufi et al. 2005; Schmitt et al. 2005b). The internal structure of protein±polysaccharide complexes has been investigated by means of in situ acidification (GDL) coupled with time resolved static light scattering for the -lg/acacia gum, -lg/pectin and -lg/xanthan gum (Girard et al. 2004; Mekhloufi et al. 2005; Laneuville et al. 2006). Results showed that more or less compact fractal aggregates were formed

442


Fig. 16.4 (a) Cryo-TEM micrographs of -lg/acacia gum aggregated complexes obtained at pH 4.0 and a protein to polysaccharide weight ratio of 2 : 1; (b) structural details of the bottom left particle after FFT filtering.

depending on the type of polysaccharide used (flexible, like acacia gum, or rigid, like xanthan gum). For acacia gum or pectin, fractal dimensions (df) ranging between 1.5 and 2.2 were found, indicating linear complexes. In the case of the xanthan gum, diffuse aggregates with df 1.8 reorganised in order to form more compact aggregate complexes with df 2.3. Interestingly, when the -lg/ xanthan system was submitted to shear, even more compact aggregates with df 2.53 were built for the same protein to polysaccharide ratio of 5:1 (Laneuville et al. 2005b). In a recent paper dealing with complex formation between lysozyme and polystyrene sulfonate with various chain lengths, small-angle neutron scattering experiments showed that three types of complexes could be formed, leading to gelled or to liquid three-dimensional structures depending on the lysozyme to PSS ratio and the PSS chain length (Cousin et al. 2005). The same group showed that when the charge ratio between the lysozyme and the PSS was close to one, the system packed into dense spheres with a radius of about 10 nm and a df 2.1 as shown by SANS and freeze-fracture microscopy (Gummel et al. 2006, 2007b). Interestingly, Leisner and Imae (2003) reported the aggregation of soluble complexes in a poly(L-glutamate)/synthetic dendrimer system into fractal ones to end up with a three-dimensional network characterizing the coacervate phase. This paper showed that the structure of the coacervate phase was very similar to that of dense aggregated complexes. In a more recent paper considering complexes built between two oppositely charged synthetic polymers, atomic force microscopy investigation allowed getting a very clear insight on the structure of the complexes adsorbed onto a mica surface (Kiriy et al. 2006). It was shown that depending on the mixing ratio, complexes were able to rearrange leading to more or less compact morphologies. The more compact ones were obtained for electrostatic neutrality. The next section considers the structural features of the coacervate phase.


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16.4.3 Microscopic level At this level of structure, liquid droplet of coacervates originating from aggregation of electrostatic complexes with various levels of hydration can be observed using light microscopy (Mekhloufi et al. 2005). However, before discussing the morphology and the coarsening of the coacervates, several studies have considered their internal structure. Upon investigation of the diffusion coefficient of protein in the BSA/PDADMAC coacervate using dynamic light scattering, two different regimes were found, indicating that the coacervate phase could behave like a heterogeneous network of polyelectrolyte chains where proteins could diffuse (Bohidar et al. 2005). Heterogeneity of structure was also reported in the -lg/pectin coacervates at various protein to polysaccharide ratios and ionic strengths (Wang et al. 2007b). It was concluded that the coacervate could be viewed as a network of pectin chains bound together electrostatically by protein molecules. In excess of proteins, some aggregates tended to form in the network. Similar description of the coacervate as a dense phase (70% of water content) was given for the whey proteins/acacia gum system after 48 hours upon small angle X-ray scattering (Weinbreck et al. 2004d). In this case, it was shown that increasing ionic strength or pH led to less homogeneous structure because the strength of the electrostatic interactions between the acacia gum chains and the whey proteins was reduced. Diffusivity measurements of the whey proteins were carried out on the same system using NMR and fluorescence recovery after photo-bleaching (FRAP), leading to the conclusion that whey proteins were free to move within the coacervates, but their diffusion coefficient was reduced in conditions where electrostatic interactions were maximum (Weinbreck et al. 2004c). Recently, the meso/ microstructure of the BSA/PDADMAC coacervate phase has been probed by FRAP (using interacting and non-interacting fluorescent probes), light scattering and cryo-TEM (Kayitmazer et al. 2006). It was shown that the coacervate was composed of dense domains concentrated in protein and polyelectrolyte and more dilute domains, leading to the different diffusion coefficients that were reported previously. It is interesting to observe in Fig. 16.4 that the inner structure of the complexes is heterogeneous with regions having differing affinities for electrons, the structural pattern being close to those observed after polymer spinodal decomposition. This section dealing with the structure of protein±polysaccharide complexes will finish with some evidence on the coacervate coarsening mechanism and some morphological properties of the coacervates. 16.4.4 Coarsening mechanism and macroscopic level The charge neutralization and aggregation of protein±polysaccharide complexes leads to the formation of liquid droplets ranging from hundreds of nanometres to several microns in diameter (Kaibara et al. 2000; Schmitt et al. 2000, 2001b). These coacervates tend to coalesce to form ultimately a dense liquid phase, as mentioned previously. The time coarsening of a -lg/acacia gum system was

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Fig. 16.5 Confocal scanning laser micrograph of aggregate-free -lg/acacia gum mixture at pH 4.2 and 1 wt% total biopolymer concentration after 3±5 min at a mixing ratio of 1 : 1. Scale bar is 5 m. From Schmitt et al. (2001b) with permission of Elsevier.

followed by static light scattering and confocal scanning laser microscopy (CSLM) after labelling of the two biopolymers (Sanchez et al. 2002). It was clearly seen that the initially formed small coacervates tended to coalesce, forming large structures characterized by solvent vacuoles, leading to the socalled sponge structure that can be seen in Fig. 16.5 for the -lg/acacia gum mixture (Menger et al. 2000; Schmitt et al. 2001b). The phase separation kinetics could be scaled with a nucleation and growth model, where initial biopolymer concentration fluctuations induced by electrostatic complex formation lead to hydrodynamically driven coalescence and formation of sharp interfaces delimiting the coacervate phase from the dilute phase (Sanchez et al. 2006). The coalescence of the coacervates was already reported by Bungenberg de Jong et al. (1940) for the gelatine/acacia gum system. It can be explained by the reduction of the interfacial energy of the system because of the appearance of interfacial viscoelasticity in the phase concentrated in biopolymers. One should recall here that the coacervate phase is mainly liquid in nature as in contains around 70% water (Schmitt et al. 2000; Weinbreck et al. 2004d). The coalescence phenomenon was shown to occur very quickly (few minutes), especially in optimum conditions of pH and protein to polysaccharide ratio (Schmitt et al. 2001b). Over time, the coacervates tend to expel the water in order to increase their free energy as demonstrated by the transition from a turbid system (because of light scattering from the water vacuoles) to a clear viscous and dense phase (Weinbreck et al. 2004c).


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16.5 Functional properties of protein±polysaccharide complexes and coacervates The formation of protein±polysaccharide complexes can potentially lead to different functional properties, compared to the two biopolymers taken individually (Schmitt et al. 1998; McClements 2006). This is generally due to a synergistic combination of the functional features of both the protein (generally hydrophobic and/or hydrophilic and globular) and the polysaccharide (generally hydrophilic and branched). In this section, the solubility and rheological properties of complexes and coacervates will be discussed, followed by interfacial properties at the oil/water and air/water interfaces. 16.5.1 Solubility and rheological properties These two functional properties are intrinsically linked to the extent of interaction between the complexes and coacervates with water. Solubility The solubility of proteins was shown to be improved upon complex formation with polysaccharide, especially close to their IEP. This property was initially used in systems composed with caseins, in order to induce colloidal stability in acidic dairy products (Payens 1972; Ambjerg Pedersen and Jorgensen 1991; Matia-Merino et al. 2004). The physical explanation for this stabilizing effect was given by Tuinier et al. (2002), who demonstrated the electrosorption of pectins onto casein micelles upon pH decrease (renneting). The formation of these pectin multilayers at the surface of the casein micelles was able to prevent strong protein aggregation mediated through hydrophobic interactions. This balance between hydrophobic attractions leading to protein low solubility and electrostatic repulsions leading to solubility was also considered upon complex formation between carboxymethylcellulose (CMC) with lysozyme or ovalbumin (Clark and Glatz 1991). Lysozyme, characterized by a high charge density, was able to form a complex with CMC, preventing further aggregation close to IEP. This was not the case for ovalbumin that had a lower charge density and a larger number of hydrophobic regions. Interestingly, several papers have reported that the formation of a complex with a polysaccharide was also preventing protein association upon heating that is known to strongly promote hydrophobic interactions (Shalova et al. 2005; Chung et al. 2007; Mounsey et al. 2008). In this case, the formation of the complex between the polysaccharide and the unfolded proteins prevented the aggregation process leading to the formation of large insoluble protein aggregates. Obviously, an important parameter controlling the solubility of the protein± polysaccharide complexes is the initial mixing ratio at a given pH and ionic strength. Incomplete charge neutralization led to the formation of soluble complexes, improving protein solubility by electrostatic repulsions or steric effects. In general, these soluble complexes were obtained close to the phase separation boundaries of phase diagrams (Schmitt et al. 2000; Weinbreck et al.

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2003b; Chung et al. 2007; Plashchina et al. 2007; Feng et al. 2007; Jourdain et al. 2008). For example, complex formation between -lg and sodium alginate at pH 5.0 was shown to induce a protein solubility of 70% when 0.75 M of sodium alginate was added to 0.5 M -lg (Harnsilawat et al. 2006a). The resulting soluble complexes were characterized by a size of around 80 nm and a -potential of ÿ40 mV, leading to strong electrostatic repulsions. Lastly, it should be noticed that for some protein purification purposes, protein± polysaccharide complex insolubility could be preferred, but this will be discussed in detail in Section 16.6 (Hansen et al. 1971; Strege et al. 1990). The formation of electrostatic complexes, and further coacervates, may induce changes in the viscosity and rheological properties of the protein±polysaccharide mixtures. Rheological properties In order to get a clear picture of the rheological properties of protein± polysaccharide complexes, this section will consider first the flow behaviour of the coacervate phase under shear, then the viscoelastic properties under small deformations and finally the gelling properties induced by temperature. The flow behaviour of the coacervate phase has been investigated for several systems and the common finding was that the flow could be described as shear thinning, i.e., the viscosity decreased when the shear rate increased to values higher than 20±30 s-1 (Burgess and Singh 1993; Weinbreck et al. 2004e; Malay et al. 2007). This result clearly indicated that the coacervate was a structured phase, whose structure could be modified when submitted to a mechanical stress. Interestingly, most of the flow behaviour of the coacervate could be related to the strength of the electrostatic interactions between the two biopolymers. Weinbreck and co-workers (2004d) reported that the viscosity of a whey protein/acacia gum coacervate phase was the highest at the EEP and was almost linearly increasing with the absolute value of the product of the potential of the two biopolymers for a given pH. A remarkable flowing feature of the coacervate phase in this case was that the system was able to recover its initial viscosity at low shear rate when submitted to a flow hysteresis. However, the authors reported that the coacervate phase took some time to reorganize after deformation, which might be an indication for some diffusion controlled events, such as alternative formation/disruption of electrostatic interactions between the whey protein molecules and the acacia gum chains. If the formation of an electrostatic network between protein and polysaccharide within the coacervate phase has already been reported for gelatine-based systems (Muchin et al. 1978), it could be proven for globular proteins by submitting the system to small oscillatory deformations (Bohidar et al. 2005). It was shown that an elastic (G0 ) and a viscous shear modulus (G00 ) could be measured in the BSA/PDADMAC system. Similar behaviour has been reported for the -lg/acacia gum coacervate, where again a frequency dependence for the two shear moduli was reported, indicating that some rearrangements were occurring at various frequencies (Schmitt et al. 2005a).


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The formation of the weak electrostatic network in the coacervate phase was also demonstrated from the ionic strength dependence of G0 in the -lg/pectin system, as it was shown that a critical value of 200 mM NaCl was screening the charges between the two biopolymers (Wang et al. 2007a). In this same study, it was found that the elastic modulus developed by the coacervate phase was also dependent on the protein to polysaccharide ratio, as was the case in -lg/xanthan gum (Laneuville et al. 2006) or pectin/poly-L-lysine systems (Marudova et al. 2004). It should also be mentioned that complex formation between globular proteins and polysaccharide could be used to produce thermogels with various viscoelastic properties (Mann and Malik 1996; Cai and Arntfield 1997). For example, heat treatment of -lg/CMC coacervate led to a viscoelastic particulate network after heat denaturation of the protein at 90 ëC (Capitani et al. 2007). 16.5.2 Adsorption at oil/water interface and emulsifying properties Due to the dual hydrophobic/hydrophilic nature of protein±polysaccharide complexes, their functionality at the oil/water interface and related emulsifying properties has been the purpose of most of the studies reporting on protein± polysaccharide functionality during these last 20 years (Gurov and Nuss 1986; Dickinson 1998; Benichou et al. 2007c). The complex formation between protein and polysaccharide was shown to affect the adsorption behaviour of the protein at the oil/water interface, but also the resulting interfacial tension. Ganzevles et al. (2007a) reported that the adsorption rate at the oil/water interface for -lg/pectin complexes was lower than for the protein alone. This difference was explained by the larger hydrodynamic radius of the complexes compared to the protein, leading to a lower diffusion coefficient in the bulk. It was confirmed by the subsequent increase of the surface tension drop rate close to that of the protein when salt was added to the system. Nevertheless, the equilibrium surface tension value reached at the equilibrium was similar for the -lg and for its complexes with pectin. Interestingly, it seemed that the lower surface adsorption rate due to diffusion was not a general rule and might be modulated by the intrinsic properties of the biopolymers. For example, a faster adsorption rate of pea globulin/acacia gum coacervates to the vaselin/oil interface was reported compared to pea globulin (Ducel et al. 2005b). Such variability in the results could be explained by the lower surface hydrophobicity of -lg compared to pea globulin, leading to a larger favourable adsorption energy for the latter complexes. These differences in the protein structure on the decrease of surface tension was clearly demonstrated for the same protein, Faba pea legumin, comparing the intact protein and a partially hydrolyzed fraction that was more hydrophobic after complex formation with chitosan (Plashchina et al. 2001). Both types of complexes were able to lower significantly the interfacial tension depending on the protein to polysaccharide ratio, but complexes with hydrolysed legumin reduced it by more than two times compared to intact protein. The reason

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probably resided in an optimal conformation of the protein at the interface, exposing the hydrophobic regions to the interface, while interacting with the chitosan chains on the bulk side, as also proposed previously for the -lg/pectin system (Ganzevles et al. 2007a). Regarding the interfacial rheology of the adsorbed films composed by protein±polysaccharide complexes, these were generally characterized by an increased surface shear viscosity, indicating formation of a dense and viscous phase at the interface of the oil droplets (Dickinson and Galazka 1992). This interfacial network formation was also highlighted from interfacial dilational measurements, where it was shown that compact layers (high dilational modulus) were formed at protein to polysaccharide ratios close to electroneutrality of the -lg/pectin complexes, whereas more diffuse layers were formed (low dilatational modulus) if the complexes were initially soluble (Ganzevles et al. 2007a). Similar behaviour was reported for a given ratio, but different pH values, in the pea globulin/acacia gum system, where the higher oil/ water interfacial elasticity was obtained for neutral complexes (Ducel et al. 2005b). It should be noticed that several studies proposed not to adsorb complexes at the oil/water interface, but to create the complexes directly at the interface after the protein has been adsorbed, using the so-called layer-by-layer method (McClements 2006). These two methods led to very different physical properties of the emulsions, especially in terms of stability, and we will review some of them in the next paragraph (Garti et al. 1999; Jourdain et al. 2008). The use of BSA/dextran sulfate complexes at a 1:3 mixing ratio was shown to improve greatly the stability of a n-tetradecane 10 wt% emulsion with no changes in size distribution for more than 3 weeks, compared to the protein stabilized emulsion (changes in size distribution after 24 hours) (Dickinson and Galazka 1992). Similar improvement of emulsion stability was described when complexes of Portulaca oleracea gum/casein complexes formed at pH 3 were used (Garti et al. 1999). It seems important to note here that the protein to polysaccharide ratio played a major role in the stabilization of emulsions stabilized by protein±polysaccharide complexes formed in the bulk vs. those formed at the interface. Hence, complexes should not be formed in charge neutralization conditions, in order to maintain sufficient electrostatic repulsions between the oil droplets. In addition, the polysaccharide should not be in excess in order to avoid oil droplets bridging flocculation. These conditions of emulsion stability were clearly demonstrated in a study involving whey protein isolate/ chitosan complexes (Laplante et al. 2006). Hence, for protein/polysaccharide ratios leading to a reduction of the interfacial net electrostatic repulsions, flocculation and syneresis of the emulsion were observed. Very similar results have been reported for whey protein/pectin stabilized emulsions (Neirynck et al. 2007). For the study involving chitosan, it should, however, be added that even if the increase of the ionic strength led to a similar reduction of interfacial charge of the droplets at a given ratio, emulsion stability could still be achieved; the likely reason being that in these conditions, more chitosan was adsorbed in the


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interfacial layer, inducing steric stabilization of the droplets (Laplante et al. 2006; Speiciene et al. 2007). Recently, Jourdain et al. (2008) showed that emulsions prepared with already formed caseinate/dextran sulfate complexes (mixed emulsions) were more stable regarding pH lowering compared to layerby-layer emulsions, which could be explained by the different interfacial structures formed at the interface in both cases. In the layer-by-layer case, the interface was probably composed by a protein layer onto which dextran sulfate adsorbed electrostatically, whereas in the case of mixed emulsion, DS formed a more compact layer together with the casein molecules and was therefore less prone to desorption at low pH. The formation and stability of layer-by-layer emulsion have been extensively studied by the group of Prof. McClements, using several protein±polysaccharide pairs, and even multilayers (Guzey and McClements 2006b). Nevertheless, Dickinson and Pawlowsky (1997) already reported that it was possible to produce a network of polysaccharide stabilized oil droplets emulsified with BSA upon controlling the quantity of -carrageenan added to the emulsion. Lower and higher polysaccharide concentrations led to depletion flocculation or aggregation of the oil droplets. Very similar results were reported for whey proteins/carrageenan stabilized emulsions (Singh et al. 2003). The creaming stability of layer-by-layer emulsions stabilized by -lactoglobulin/pectin or -lactoglobulin/ -carrageenan towards pH and ionic strength environmental stresses was shown to be improved by secondary emulsification by ultrasound or secondary emulsification in an -carrageenan dispersion (Guzey et al. 2004; Gu et al. 2005a, 2005b). Both techniques allowed creation of protein±polysaccharide multilayers at the oil droplet interface. Interestingly, these results led to the design of multilayered emulsion composed by the superimposition of several protein±polysaccharide layers, such as, for example, -lactoglobulin/carrageenan/gelatine, each layer being able to respond specifically to an environmental stress, such as, for example, pH change, ionic strength increase or temperature change (Gu et al. 2005b). This latest interfacial engineering might be useful for the development of functional capsules to be used in food applications, and will be discussed in the next section. We now turn to a review of the air/water interfacial and foaming properties of protein/polysaccharide complexes and coacervates. 16.5.3 Adsorption at air/water interface and foaming properties The ability of protein±polysaccharide electrostatic complexes to stabilize the air/ water interface was reported early for the whey protein/carboxymethylcellulose system (Hansen and Black 1972). Thus, these complexes exhibit air/water surface activity due to their amphiphilic nature, as was the case for oil/water interface stabilization. It was shown that complexes obtained between BSA and -carrageenan were able to lower the air/water interfacial tension, to the same extent as BSA alone, but at a reduced adsorption rate (Dickinson and Pawlowsky 1997). This delay in interfacial adsorption might be related to the reduced

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diffusion coefficient of the complexes compare to the protein alone. This hypothesis was confirmed for the -lg/pectin system (Ganzevles et al. 2006a). It was shown that the rate of surface pressure increase was lower for conditions where more protein±polysaccharide complexes were formed, i.e., for lower pH values or high protein±polysaccharide ratios. An interesting feature of this system was also that pectins with a lower degree of esterification (more negative charges) were delaying more importantly the interface adsorption because of the size of the complexes formed compared to highly esterified pectins (Ganzevles et al. 2006a). Similar observations of lower diffusion at the air/water interface were made upon adsorption of ovalbumin/pectin complexes at acidic pH (Kudryashova et al. 2007). Results on adsorption kinetics might be triggered by the molecular characteristics of the polysaccharide. Hence, complexes of -lg with the globular polysaccharide acacia gum were able to lower interfacial tension as fast as the protein alone (Schmitt et al. 2005a). This might be due to the more compact structure of these complexes compared to pectin-based ones, pectin molecules being more linear biopolymers than acacia gum. This hypothesis was tested recently on a system composed by -lg interacting with pullulan grafted with carboxyl group leading to charge densities ranging from 0.1 to 0.61 (Ganzevles et al. 2007b). It was shown that the adsorption kinetics were lowered for the -lg/pullulan complexes having the highest charge densities, which in turn led to the soluble complexes with the largest hydrodynamic radius. The interfacial properties of the protein±polysaccharide films were shown to be strongly dependent on the way complexes were formed. Complex formation at the interface led to dilational modulus up to two times higher than for complexes adsorbed from the bulk (Ganzevles et al. 2006b). The authors explained that, in the first case, pectin molecules were able to reinforce the existing adsorbed protein layer, whereas in the second case, protein adsorbed less easily at the interface due to its interaction with the pectin chains. Interestingly, it was shown that the surface shear modulus was independent of the protein±polysaccharide ratio for the already adsorbed protein layer, but was maximized when complexes formed in the bulk reached electroneutrality. Neutral -lg/acacia gum complexes were also shown to increased interfacial dilational viscoelasticity compared to the protein alone (Schmitt et al. 2005a). This led also to thicker interfacial films with reduced gas permeability and increased lifetimes (Schmitt et al. 2005a; Liz et al. 2006). Schmitt et al. (2005b) reported the importance of possible rearrangements of -lg/acacia gum complexes at the interface on the stability of the resulting air/bubble and foams. Adsorption of neutral complexes led to thick viscoelastic hydrated films with low gas permeability, whereas already formed coacervates led to thin elastic films with lower water content and higher gas permeability. Figure 16.6 clearly shows the formation of a thick interfacial layer composed of -lg/acacia gum complexes having rearranged into a coacervate phase at the interface of air bubble within foam at the EEP. Interestingly, flowing isolated coacervates could be seen in the Plateau border (due to gravitational drainage), but were not


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Fig. 16.6 Confocal scanning laser micrograph of aqueous foam stabilized by fluorescently labelled -lg/acacia gum complexes and coacervates at a total biopolymer concentration of 1 wt% at pH 4.2 and a protein to polysaccharide ratio of 2 : 1. Arrows indicate interfacial layer stabilized by fused coacervates and free coacervates draining in the thin-film. Scale bar is 50 m. Copyright NestleÂ Research Center, Lausanne.

integrated into the interface. Ganzevles et al. (2007b) also reported that varying the charge density of the pullulan (by grafting of carboxylic groups) upon complex formation with -lg led to various interfacial shear moduli at the air/ water interface. In this case, the polysaccharide was controlling the protein conformation at the interface through its charge density by the formation of more or less compact complexes. Several studies reported the improved foam stabilization properties of protein±polysaccharide complexes and related the improvement compared to the single protein mainly to a combined effect of interfacial properties but also from the local increase of the bulk viscosity in the thin-films due to the formation of the complexes (Poole 1989; Ahmed and Dickinson 1991; Glaser et al. 2007). As was shown above, protein±polysaccharide complexes exhibit a variety of functional properties enabling their use in several food and non-food applications (Samant et al. 1993; Schmitt et al. 1998; Cooper et al. 2005), and these are now discussed in Section 16.6 and 16.7, respectively.

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16.6 Food applications of protein±polysaccharide complexes and coacervates Some food and non-food applications of protein±polysaccharide complexes and coacervates will overlap (protein separation, microencapsulation). Nevertheless, in order to give a clearer overview of both fields, these applications will be considered separately. In this section, we consider the use of complex and coacervate formation for protein purification, microencapsulation, production of fat substitutes and texturization in food products. In the last subsection, some other food applications will be reviewed. 16.6.1 Protein purification The differences in the IEP of the various food proteins allow recovering them selectively by complex formation with polysaccharides upon proper adjustment of the environmental conditions such as pH, ionic strength and protein to polysaccharide ratio. This purification method offers the advantage of not using organic solvents. In addition, it enables the re-use of the polysaccharide and allows large-scale purification processes. The main drawback is that it is mainly a batch process, unless the polysaccharide can be immobilized on a support. Several studies reported on the extraction of the major whey protein fractions upon complex formation with carboxymethylcellulose (CMC) in acidic conditions (Hansen et al. 1971; Hill and Zadow 1974). For example, it was shown that BSA and -lg could be specifically removed from whey at pH 4.0 using CMC. Further decrease of the pH to 3.2 enabled extraction of -la, the remaining soluble fraction being composed mainly of proteose peptones (Hidalgo and Hansen 1971). Similar results could be obtained using apple pectin that allowed recovery of 90% of all the whey proteins at pH 3.4, but with no selectivity (Serov et al. 1985). Whey protein recovery could also be achieved in basic pH conditions when chitosan was used for complex formation. For example, up to 90% of -lg could be removed from cheese whey upon complex formation with chitosan at pH ranging from 8 to 10 and ionic strengths ranging from 0.08 to 0.3 M (Montilla et al. 2007). Interestingly, a variety of other proteins (e.g., soy or potato proteins) could be fractionated using the same principle (Smith et al. 1962; Vikelouda and Kiosseoglou 2004). For example, an efficient and simple technique for isolation of immunoglobulins Y (IgY) from egg yolk by anionic polysaccharides was developed (Chang et al. 2000). These proteins can be used as immunological supplements in infant formulae and other foods. Isolation conditions of IgY in egg yolk were optimized by the addition of various levels of Na-alginate, -carrageenan, Na-CMC, and pectin to diluted egg yolk. It was found that the pH value of the polysaccharide±yolk mixture affected both the quantity of polysaccharide-lipoprotein precipitates and the immunoactivity recovery of IgY. The IgY recovery was determined to be 33±74% by means of single radial immunodiffusion method when IgY was isolated under optimal conditions. Among the polysaccharides tested in this


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study, the use of 0.15% pectin exhibited the best immunoactivity recovery of IgY at pH 5.0. 16.6.2 Microencapsulation In food applications, microencapsulation can be used in order to protect food bioactive molecules that are sensitive to external stresses such as pH, oxygen content or temperature (Table 16.2). For example, Oliveira et al. (2007) evaluated the resistance of microcapsules containing Bifidobacterium lactis and Lactobacillus acidophilus, produced by complex coacervation using a casein/ pectin system, to the spray drying process, a shelf-life of 120 days at 7±37 ëC and the in vitro tolerance after being submitted to acid pH (pH 1.0 and 3.0) solutions. The process used and the wall material were efficient in protecting the micro-organisms; however, microencapsulated Bifidobacterium lactis lost its viability before the end of the storage time. Other important uses could be to provide a controlled release of aroma or flavours before or upon consumption of the food or even to mask the bad taste of some biologically active material (Gouin 2004). Any type of triggers can be used to prompt the release of the encapsulated ingredients, such as pH changes, mechanical stress, temperature, enzymatic activity, time, osmotic force, etc. In the case of probiotics, the use of microencapsulation for controlled-release applications is a promising alternative to solving the major problems of these organisms that are faced by food industries (Anal and Singh 2007). The probiotics are protected from bacteriophage and harsh environments, such as freezing and gastric solutions and their encapsulated form can be used in many fermented dairy products, such as yoghurt, cheese, cultured cream and frozen dairy desserts, and for biomass production (Anal and Singh 2007). Yeo et al. (2005) used temperature as a trigger to controlled release of flavour oil to improve the appeal of frozen baked foods upon heating. They have encapsulated flavour oil in complex coacervate microcapsules using gelatine and gum arabic. The oil remained encapsulated for 4 weeks of storage at 4 and ÿ20 ëC (freezing and thawing) but was released by exposure to 100 mM NaCl at room temperature. When particles were cooled after releasing their oil content, the oil was re-encapsulated. It is worth mentioning that two methods of encapsulation can be followed for food applications. Interfacial complex coacervation or layer-by-layer deposition around an oil phase can be used. This technique generally leads to microcapsules having diameters ranging from 1 to 50 m (Lamprecht et al. 2001; Weinbreck et al. 2004a). Alternatively, complexes can be formed at the surface of a protein or polysaccharide matrix, leading to sub-micrometer particles (Chen and Subirade 2005; Hong and McClements 2007). In both cases, the oil phase and the matrix contain the molecule(s) of interest. In the case of oil droplet encapsulation, besides the fact that pH, ionic strength, protein to polysaccharide ratio or total biopolymer concentration must be optimized, an important subsequent processing step is to stabilize the

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Table 16.2 Examples of protein±polysaccharide systems used for microencapsulation purposes in food and non-food applications Systems Food applications Whey protein isolate/ xanthan gum, /fenugreek gum Whey protein isolate/ xanthan gum, /galactomannans 2-gliadin/, pea globulin/ acacia gum Gelatine/acacia gum Whey protein/gum arabic Gelatine/gum arabic

Technique/Encapsulated material

References

Oil in water in oil emulsion/ Medium chain trigycerides/ triacetin, flumethrinÕ Water in oil in water emulsion/ Medium chain triglycerides, vitamin B1 Oil in water emulsion/Medium chain triglycerides Oil in water emulsion/ Eicosapentaenoic acid ethyl ester (EPA) Oil in water emulsion/Lemon and orange oil flavour Oil in water emulsion/10% natural oils from anise, oregano, garlic, black pepper in 90% vegetable oil

Benichou et al. (2007a)

Non-food applications Gelatine/acacia gum Oil in water or water in oil emulsion using microchannels/Soybean oil Gelatine/gum arabic Oil in water emulsion/Paraffin oil Alginate/poly-L-lysine Aqueous coacervation and CaCl2 reticulation/Erythropoietin-secreting cells Gelatine/acacia gum Oil in water emulsion/ Methoxybutropate Gelatine/sodium Oil in water emulsion/Dalarelin alginate Gelatine/acacia gum Oil in water or water in oil emulsion/Clove oil, sulphamethoxazole Gelatine/acacia gum/ Oil in water emulsion/Capsaicin tannins Gelatine/acacia gum Oil in water microemulsion/ Cypermethrin

Benichou et al. (2007b) Ducel et al. (2004) Lamprecht et al. (2001) Weinbreck et al. (2004a) Yeo et al. (2005)

Nakagawa et al. (2004) Mayya et al. (2003) Murua et al. (2007) Palmieri et al. (1999) Ryszka et al. (2002) Thimma and Tammishetti (2003) Xing et al. (2003) Zhu et al. (2005)

interface against pH and ionic strength changes to avoid capsule disruption. Hence, it has been clearly shown that unstabilized microcapsules were much more sensitive to leakage or oxidation than crosslinked ones (Weinbreck et al. 2004a). If this can be achieved by formation of covalent bonds between protein and polysaccharide by use of glutaraldehyde for non-food applications, other biocompatible means of crosslinking have been developed for the food industry.


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Some authors described the formation of multilayers around the oil droplets, each layer being sensitive to different environmental stresses (Harnsilawat et al. 2006b). Another approach could be to use food grade solvents (ethanol) or spray drying to dehydrate the interfacial coacervates as has been shown for gelatine/ acacia gum capsules loaded with -3 unsaturated fatty acids (Lamprecht et al. 2001). Interestingly, it was recently shown that the use of glycerol to crosslink gelatine/acacia gum capsules loaded with sesame oil extract led to similar results to capsules crosslinked with formaldehyde (Huang et al. 2007). An alternative solution is to use an oxidizing agent such a dihydroascorbic acid or even `foodgrade' crosslinking enzymes (Weinbreck et al. 2003a; Strauss and Gibson, 2004; Littoz and McClements 2008). The obtained microcapsules can thereafter be introduced in a food matrix and release aroma and bioactives, as has been shown for limonene-loaded whey protein/acacia gum capsules in Gouda cheese (Weinbreck et al. 2004a). When a protein or a polysaccharide matrix is used, stabilization can be achieved by subsequent heat treatment of the system. This promotes strong hydrophobic interactions in addition to the initial electrostatic ones as has been shown for -lactoglobulin/chitosan complexes (Chen and Subirade 2005; Hong and McClements 2007). Nevertheless, it was also shown that non-heat-stabilized chiosan/ -lg core/shell nanoparticles loaded with brilliant blue were less prone to acid and pepsin degradation in simulated gastric conditions, probably because of the different reactivity of native and denatured forms of -lg (Chen and Subirade 2005). 16.6.3 Food products texturization Protein±polysaccharide complexes have been shown to be able to control gellike product texture or replace fat or meat in several food applications (Sanchez and Paquin 1997; Schmitt et al. 1998; Norton and Frith 2001). Owing to the rheological and heat sensitivity of several globular proteins and fibrillar polysaccharides, appropriate processing conditions (heat treatment, homogenization) allowed the production of mixed microparticles matching the textural attributes of fat (spherical aggregates in the range of 1±10 m) or meat (fibrillar aggregates in the range 1 to 50 m). For example, Chen et al. (1989) reported the use of microfragmented milk and/or egg proteins/xanthan gum complexes obtained upon interaction at pH 3.7 to 4.2 as a fat substitute. The formed complexes had a diameter of around 15 m, which is close to values reported for electrostatic complexes between whey proteins and xanthan gum (Laneuville et al. 2000). These fibrillar complexes were thereafter heat treated to increase their stability by exposure of hydrophobic regions of the protein and microfragmented under high pressure (200±800 bars) and shearing, leading to microparticles of about 2 to 10 m. Such whey proteins/xanthan gum complexes were shown to efficiently allow reduction of fat in cake frostings or sandwich cookie fillings, provided that the amount of complexes was adapted to the water activity of the sample (Laneuville et al. 2005a). Recently, it was shown that

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thermogels with a very wide range of texture could be obtained upon complex formation of -lg or -la with carboxymethylcellulose (Capitani et al. 2007). The production of meat substitutes was achieved in a very similar way, but in this case, alginate and pectins were used to complex milk and soy proteins (Tolstoguzov et al. 1974). Interestingly, it was also shown that texturization properties could be obtained without requiring a heat treatment of the complexes as was the case for chitosan/chicken salt-soluble proteins (Kachenechai et al. 2007) or amidated pectins and sodium caseinate (Matia-Merino et al. 2004). In this respect, polysaccharides played the function of electrostatic crosslinking agents. Recently, similar modulation of protein gel texture was reported upon insitu acidification of -lg/xanthan gum (Laneuville et al. 2006) or skimmed milk/ exopolysaccharide mixtures using GDL (Girard and Schaffer-Lequart 2007). In these studies, the importance of the molecular weight of the xanthan gum or the molecular structure of the exopolysaccharides in the rheological properties of the obtained gels was clearly shown. 16.6.4 Interface stabilization Protein±polysaccharide complexes can be used to stabilize interfaces in several food products. For example, creaming stability of a 30 wt% soya oil emulsion stabilized by whey protein isolate/-carrageenan complexes (Singh et al. 2003) and 40 wt% rapeseed oil stabilized by whey protein isolate/chitosan complexes (Speiciene et al. 2007) could be efficiently improved in acidic conditions. This was due mainly to the formation of a weak electrostatic network between the oil droplets, as it has been previously described for cold-protein gels. Use of spray dried complexes made of whey protein and carboxymethylcellulose (CMC) was tested in order to stabilize 10 or 20 wt% corn oil in comparison to pure whey protein isolate (Girard et al. 2002b). It was concluded that the complexes were clearly improving the stability of the oil droplets against coalescence, but were promoting some flocculation due to the presence of a minor fraction of uncomplexed CMC. Similar freeze-dried complexes at a concentration of solids of 4 wt% were able to produce very dense and thick foams that were very close to those obtained with egg white (Hansen and Black 1972). Poole (1989) reported the very high foaming and foam stabilizing properties of whey protein/chitosan complexes in a model sucrose/corn oil emulsion, likely because complexes were encapsulating the fat, preventing its detrimental spreading at the air/water interface. More recently, the use of whey protein isolate/acacia gum complexes was shown to improve significantly the heat shock stability of air bubbles within a complex acidic ice cream matrix (Kolodziejczyk and Schmitt 2004). Figure 16.7 shows whey protein isolate/ acacia gum complexes formed instantaneously in the ice cream mix during whipping/freezing and adsorbed at the interface of the air bubbles. A coacervate layer was formed, conferring very low gas permeability to the bubbles upon several freeze/thawing cycles.


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Fig. 16.7 Confocal scanning laser micrograph of a strawberry ice-cream stabilized by whey protein isolate/acacia gum complexes and coacervates at pH 4.2 after 7 days of storage at ÿ40 ëC. The protein was coloured by the rhodamine 6G reagent. Arrows indicate the coacervates adsorbed at the interface of the air bubbles. The scale bar is 20 m. From Kolodziejczyk and Schmitt (2004). Copyright NestleÂ Research Center, Lausanne

16.6.5 Other food applications Some other food applications of protein±polysaccharide complexes might be the design of edible films as has been described for a system composed by soy protein/sodium alginate or /propylene glycol alginate (Shih 1994). Interestingly, it was recently shown that a combination of lysozyme and chitosan with an edible film was able to confer a very high potential for antimicrobial activity (Park et al. 2004). In this case an important parameter to control was the protein to polysaccharide ratio that was both controlling the antimicrobial activity, but also the physical properties of the film. Finally, it has recently been shown that protein±polysaccharide complexes were probably importantly involved in some in-mouth fat perception attributes as the flocculation of lysozyme-stabilized emulsion was due mainly to interaction with the glycated saliva mucin proteins (Silletti et al. 2007). Interestingly, such type of electrostatic complex formation has also been discovered between mucins and chitosan (Dedinaite et al. 2005).

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16.7 Non-food applications of protein±polysaccharide complexes and coacevates A variety of applications of protein±polysaccharide or protein±polyelectrolyte complexes can be described. They range from hydrogels for protein or enzyme release and entrapment, synthesis of biosensors, use as surfactants in cosmetic applications (T.X. Wang et al. 2000) to protein separation (Strege et al. 1990) as it was already the case for food applications. Recent examples of these applications can be found in a very detailed review by Cooper et al. (2005). In the next two subsections, we consider mainly uses for microencapsulation and synthesis of biomaterials. 16.7.1 Microencapsulation An important field for non-food applications of protein±polysaccharide complexes and coacervates is microencapsulation for the pharmaceutical industry (Burgess 1994; Table 16.2). Early on, Bungenberg de Jong (1949b) reported that is was possible to entrap carbon particles or ink directly into the dispersed gelatine/acacia gum coacervate phase. This technique was also used to encapsulate micronized Naproxen into gelatine A/gelatine B microcapsules (Burgess and Carless 1985). The drug was dispersed in glycerol and mixed with gelatine B dispersion before coacervation occurred. The yield of drug encapsulation was around 50% in the best conditions of protein to polysaccharide ratio and temperature. In the same vein, Ryszka et al. (2002) reported the preparation of microcapsules in the form of a biodegradable coacervate containing dalarelin (analogue of the gonadotrophin-releasing hormone), with a gelatine/alginate coating. The microcapsules were obtained with yield of 66:4 2:1%. It was found that the dalarelin in the form of microcapsules had better bioavailability and was active longer in rats when compared with the dalarelin solution injections. Ponsart and Burgess (1996) reported the encapsulation of the -glucuronidase enzyme into three different coacervating systems consisting in gelatine/acacia gum, gelatine/sodium alginate and BSA/acacia gum in the optimum coacervation conditions of pH, ionic strength and protein to polysaccharide ratio. Stabilization of the microparticles was achieved by spray drying, leading to diameters around 5 m. The enzyme encapsulation yield was shown to be low, 28.8%, but was, however, higher than for non-spray-dried microparticles (11.3%). Interestingly, it was shown that the activity of the enzyme could be maintained upon hydration of the microparticle in phosphate buffer over a period of 8 days, revealing the interesting controlled release properties of these systems. Recently, a similar approach was used to increase the oral delivery of low molecular weight heparin, tinzaparin, which is not highly negatively charged (Lamprecht et al. 2007). In this case, an encapsulation yield of more than 90% was obtained using gelatine A or B in combination with acacia gum. Oral delivery quantification showed that gelatine B particles lead to 4.2% oral


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absorption compared to no adsorption with the pure protein or in gelatine A/ acacia gum particles, showing the importance of the microparticle charge for promoting adsorption at a given pH. Xing et al. (2006) studied the antimicrobial activities of capsaicin microcapsules prepared by the complex coacervation of gelatine, acacia gum and tannins. The results showed that the optimum pH for the antimicrobial effect was about 5.0, which might be related to the strongest protein-precipitating ability of tannins at this pH value. Another type of sub-micronic pH sensitive particles was obtained upon complex formation between chitosan and ovalbumin (Yu et al. 2006). Worth noting was the fact that the hydrophobicity/hydrophilicity of these nanogels could be triggered upon pH adjustment as was demonstrated from fluorescence spectroscopy upon pyrene addition. It was shown that between pH 2 and 5, nanogels were hydrophobic, whereas they became more hydrophilic up to pH 6.8. The likely explanation was the change in the intensity of the electrostatic interactions between the two biopolymers upon pH increase, leading to several molecular conformations of the chitosan chains within the gels. Another common way of producing microcapsules using complex coacervation is to achieve interfacial coacervation around an oil droplet as already described for food applications. Such technique allows encapsulating hydrophobic molecules that cannot be easily dispersed in the coacervate phase. This was done for example for the anti-inflammatory drug, ketoprofen, using gelatine/acacia gum microcapsules (Palmieri et al. 1996). Recently, Lamprecht et al. (2000) gave a very interesting insight into the structure of the microcapsules made of gelatine and acacia gum around oil droplets. Using confocal scanning laser microscopy, they were able to localize specifically the two biopolymers into the shell of the microcapsule and demonstrated that the two biopolymers were evenly distributed. Remarkably, the authors showed that if a ternary labelled hydrophobic protein was used (casein in this case), it had the tendency to adsorb preferentially at the oil/water interface, enabling an additional control of the release of the encapsulated material. The same system was used by Mayya et al. (2003) to encapsulate paraffin oil in the presence of sodium dodecyl sulfate. They reported that encapsulation yield increases from 35% to 70% in the presence of small quantities of the oppositely charged surfactant. 16.7.2 Biomaterials Another important field of use of protein±polysaccharide complexes is the synthesis of biomaterials. When used as biomaterials and matrices in tissue engineering, biopolymers offer important options to structure, morphology and chemistry as reasonable substitutes or mimics of extracellular matrix systems (ECM). These features also allow controlling material functions such as mechanical properties in gel, fibre and porous scaffold formats (Velema and Kaplan 2006). Hence, as these materials are supposed to be in direct contact with living organisms, replacing the extracellular matrix, they should be

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composed with biopolymers that can be found in the organisms or be as close as possible in terms of structure (Ellis and Yannas 1996). In this respect, chitosan was shown to be relatively close to the structure of glycosaminoglycans (GAGs) occurring in living cells. It was therefore extensively used as a complex with collagen or with its hydrolysate product, gelatine. Taravel and Domard (1996) studied the interaction of collagen with chitosan and reported on the mechanical and structural properties of the films that were obtained. Such structural properties are very important in order to control the assimilation of the biomaterial by the living body, as, for example, the porosity of the protein±polysaccharide-based ECM was shown to control the speed development and colonization of the graft by the fibroblasts. Porosity could, for example, be modulated by controlling the freezing rate upon drying of collagen/ GAG complexes (O'Brien et al. 2004). Interestingly, protein±polysaccharide complexes could also serve as a carrier for bioactive molecules in gene therapy as has been shown for the delivery of plasmid DNA to articular chondrocytes using a collagen/GAG matrix (Samuel et al. 2002). Here, it was shown that DNA incorporated in the scaffold at pH 7.5 was better released over 28 days upon incubation in Tris-EDTA buffer compared to pH 2.5. In addition, DNA kept a more `natural' coiled structure in neutral pH conditions. Erbacher et al. (1998) studied pharmacological approaches to gene therapy based on non-viral DNA vectors using chitosan to form polyelectrolyte complexes. They found that chitosan presents some characteristics favourable for gene delivery, such as the ability to condense DNA and to form homogeneous population of complexes (diameter: 50±100 nm). The characterization of physico-chemical properties of this system was carried out by Mao et al. (2001). They also confirmed the offered protection for encapsulated DNA from nuclease attack. Recently, the in vitro and in vivo transfection efficiency of chitosan-pDNA nanoparticles obtained by complex coacervation were studied using quaternized chitosan ± 60% trimethylated chitosan oligomer (TMCO60%) ± and two other chitosan molecules differing in molecular weight (Fang et al. 2007). It was found that TMCO-60%/pDNA nanoparticles had better in vitro and in vivo transfection activity than the other two molecules, with especially most prominent delivery in the gastric and upper intestinal mucosa. In the same vein, it was recently shown that 5±10 m chitosan/gelatine microspheres could be used for controlled and site-specific release of fibroblasts growth factor (Liu et al. 2007). It was shown that the growth factor released could be extended for 14 days, with an accumulated release yield of around 72% leading to a significant development of fibroblasts compared to a control with no added micropheres.

16.8

Conclusions

In this chapter, we have attempted to give a concise overview of the field of protein±polysaccharide complexes and coacervates. Thanks to the development


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of new investigation techniques and the use of computer simulations, increasing knowledge has been acquired on these systems in the last few years. Hence, thermodynamic parameters of the complex formation/coacervation are now accessible, enabling the probing and refining of theories from the late 1950s. However, more refined thermodynamic binding models are needed to take into account the inherent complexity of thermograms obtained with protein± polysaccharide mixtures, especially the existence of both exothermic and endothermic signals. In addition, computer simulations on monodispersed model systems allow prediction of phase behaviour and complex formation in relatively simple real synthetic or semi-synthetic systems. Increasing complexity of the models with experimentally measurable parameters would be required for application to more polydispersed natural systems and for more complex biomolecular architectures. In this respect, one would also expect models enabling prediction of the phase separation kinetics in protein±polysaccharide systems to be developed. The use of mesoscopic and multi-scale modelling techniques can be anticipated in the next few years. An important contribution to the understanding of the complex and coacervate structure was permitted by the use of novel scattering and microscopy techniques, such as, for example, confocal scanning laser microscopy (CSLM) coupled with fluorescence recovery after photobleaching (FRAP) or particle tracking. Such experiments clearly demonstrated the dynamics of the coacervate phase that can be compared to a heterogeneous electrostatic network of polymers exhibiting capability to diffuse along the polyelectrolyte chains; the diffusion being controlled by the strength of the electrostatic interactions between the protein and the polysaccharide (depending on pH, ionic strength, mixing ratio and other biopolymer intrinsic properties). In the last few years, emphasis has been given to extend the study of the functional properties of these complexes and coacervates, enabling identification of several interesting fields of applications in food and non-food products. Thus, the rheological and interfacial properties of protein±polysaccharide complexes might be advantageously used for designing food products with various textures, stability and delivery properties. The same conclusions apply to non-food applications, where an increased number of studies reported on the formulation of novel delivery systems sensitive to environmental stresses, enabling specific controlled release of bioactive molecules in the right organs or tissues. In order to expand the different applications, especially at the industrial scale, it would be necessary to better understand the effects of processing conditions such as temperature, shear stresses and pressure on the structure, stability and functional properties of protein±polysaccharide complexes and coacervates. Also, since the formation of protein±polysaccharide complexes and coacervates is mostly totally reversible upon pH changes, stabilization of these systems using physical parameters or by using specific enzymes or chelating biological molecules is expected to be developed in the future.

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16.9

Acknowledgements

The authors would like to thank Dr Eric Kolodziejczyk from NestleÂ Research Center for providing Figs 16.6 and 16.7.

16.10

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17 Gum ghatti S. Al-Assaf, G. O. Phillips and V. Amar, Glyndwr University, UK

Abstract: This chapter describes the natural tree exudate gum from India. The exudate gum has a glassy appearance and the colour can vary from dark red to translucent white depending on the shape which can be either as a nodule or spiro. The chapter then reviews the structure and botanical source of gum ghatti. Technical information relating to its solubility, sugar composition, protein content, molecular weight, viscosity and emulsification performance are directly compared with gum arabic. Gum ghatti's current regulatory status together with various food and other applications are also described. Key words: gum ghatti regulatory status, ghatti molecular weight, ghatti in beverage emulsion, ghatti applications, GATIFOLIA.

17.1

Introduction

Gum ghatti is a natural gum from India. It is exuded from the tree species Anogeissus Latifolia which is native to India and Sri Lanka. These trees constitute one of the largest forest coverages in India and are found mostly in dry deciduous forests. This tree can survive in harsh conditions and does not need a lot of water to survive, although if proper nutrients are provided this tree can grow very healthy and large. Gum exudation occurs during times of stress for the tree. The exudation process occurs very slowly over a period of days and depending on the size or age of the tree. The exuded gum nodules can range from 5 g to 50 g in weight. The shape of the exuded nodule depends on environmental conditions such as wind, sunlight, heat and other factors like the mass of the nodule, the pressure within the tree and the shape/size of the fissure from where the gum is exuding. There is no particular shape for a ghatti nodule as found for gum arabic variety Acacia senegal. Gum ghatti has a glassy appearance and the

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Fig. 17.1 (left) Gum ghatti nodule known in the industry as `SPIRO'; (right) gum ghatti nodule in a rounded tear shape.

colour of the nodule can vary from dark red to translucent white. The gum is collected in much the same way as most other natural tree exudate gums such as gum arabic and gum karaya. The local community in the forest region (Tribals), who constitute the main population of the forest areas, collect the exudate manually. These Tribals have extensive knowledge about the character of the trees in their local habitats, and provide a very good source of knowledge about the natural gum exudation and tree identification. Figure 17.1 shows two types of exudates known as a Spiro exudation which is clear and tubular in form and a rounded tear shaped nodule from trees in the Central Indian Forest. The tree grows on a well-drained slope and clay loam soil, and attains considerable height towards maturity in about 70±80 years. On dry rocky slopes, however, it tends to be stunted. It has a peculiar bark, smooth and greenish white in colour, and about 4±5 mm thick. The leaves are shaped somewhat like those of guava. Varying between 5 and 10 cm in length and 3 and 8 cm in width, these are alternate or sub-opposite in arrangement. These are thick and somewhat shining. Old leaves are shed between October and December, when these tend to get a beautiful reddish-brown hue. New leaves appear during February±March. Inflorescence starts appearing during May and stays on up to the end of June. The small flowers are off-white. Fruits start to show in July. When about to mature, these 8±10 mm 5±6 mm drupes are peculiarly compressed, showing a two-winged form. The ghatti tree grows best in the sunny aspect of peninsula ranges, Shivaliks and outer Himalayas at altitudes ranging from 200 m to 1250 m, and experiencing annual rainfall of 100±200 mm and temperatures varying from 5 to 40 ëC. However, it is quite capable of surviving in adverse climatic and geological conditions like dry rocky slopes. This tree has a moderate rate of growth. It has seven annual rings of growth in an inch of the cross section of its stem. Thus weighing about 28 to 32 kg to a cubic foot, it is one of the best hardwoods on the Indian sub-continent. Though quite difficult to season, it tends to split if left unattended in the sun. The splitting is less if the logs are kept in shade for about six months and sawn pieces are also kept in shade for a long period.

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The gum is exuded from the bark of the tree and can be found all over the tree irrespective of the location such as a branch or the trunk, etc. The gum is exuded from the tree in extreme climatic conditions and acts as the buffer stock of nutrients required by the tree for survival. There is no need to make wounds in the bark of this tree to exude the gum as is the common practice with some other natural tree exudate gums. The gum exudation from this species is mostly due to the pressures created within the bark due to extreme natural conditions. The gum comes naturally from the bark and can be collected by pulling the soft gel-like exude which collects on the tree bark at certain locations. If the gum is not plucked/picked from that location, fresh gum will not exude from the same position again. In order to increase the yield the common practice is to pick the old gum and make way for fresh gum to flow. The gum when freshly exuded has high moisture content and is very soft. When left in the open for days, the gum nodule loses moisture and hardens giving the nodule a rounded tear-like shape which is very hard and does not change. The gum has a faint sweetness to taste and a very faint odour which can only be recognised when the gum is kept in large volumes. Within the Genus Anogeissus several species have been identified: A. acuminata (A. pendula), A. bentii, A. dhofarica, A. latifolia, A. leiocarpus (A. leiocarpa), A. rotundifolia, A. Schimperi and A. sericea. The specific gum which is being described here is the species Latifolia with the following botanical taxonomy: Kingdom: Plantae Phylum: Angiosperms Class: Magnoliatae Subclass: Rosidae Order: Myrtales Family: Combretaceae Genus: Anogeissus Anogeissus is a genus of trees native to South Asia, the Arabian Peninsula, and Africa, belonging to the family Combretaceae. The genus has eight species, five native to South Asia, two endemic to the southern Arabian Peninsula, and one native to Africa. Anogeissus latifolia is one of the most useful trees in India. A. pendula is common in the Kathiarbar-Gir dry deciduous forests of western India, where it often forms pure stands in the rocky ridges of the Aravalli Range. A. leiocarpus is found in Africa from northeastern Ethiopia to Senegal, and its bark is used to produce Anogelline, a substance used in cosmetics. A. dhofarica and A. bentii are endemic to the woodlands of the southern Arabian Peninsula. Gum ghatti is known by many names throughout India and the rest of the world. It is commonly known as Bakli, Tirman, Davedi, Dindal, Dindiga, Dhanta, Dhao, Dhawra, Dhokra, Dho, Kardhai in different parts of India. Elsewhere in the world it is referred to as Indian gum, Gummi indicum, Gummi indici and the tree is known as axlewood in the United States and Australia.

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17.2

Manufacture

The gum is usually supplied from the original producer in India to the global industry in lump form without any particular manufacturing process being applied. It is, nevertheless, distinguished on the basis of the amount of extraneous contamination present in the raw material. The main factors that contribute to purity are the colour and extraneous material. White, yellow and red grades are distinguished. There could be further grading according to the quality of the gum in which all the impurities such as bark, wood, sand, and nonghatti products, etc., have been removed. In the past this mixture of different types was an inherent weakness, since the gum reaching the market in terms of colour, gel content and solubility, was very variable. Now, due to the establishment of a plantation, selection and cleaning before exporting, the quality has greatly improved. Due to this more recent improvement, it has been possible to produce a gum quality by special processing and spray drying which is almost completely soluble and of consistent colour. This special product has been termed GATIFOLIA.

17.3

Structure

Gum ghatti has an extremely complex structure composed of sugars such as Larabinose, D-galactose, D-mannose, D-xylose, and D-glucuronic acid in a 48 : 29 : 10 : 5 : 10 molar ratio.1 The gum contains alternating 4-O-subsituted and 2-O-subsituted -D-mannopyranose units and chains of 1 ! 6 linked -Dgalactopyrannose units with side chains which are most frequently single Larabinofuranose residues. Using 13C NMR spectroscopy suggested that ~6% of rhamnose are linked as side chain to the galactose backbone as -Rhap-(1 ! 4) -galactopyrannose in common with the linkage found in gum arabic.2 Most of the information that we have about the structure of the polysaccharide components of gum ghatti has come from the classical work of that doyen of polysaccharide chemistry, Professor Edmund Hirst together with his colleague Gerald Aspinall and their co-workers over the period 1955 to 1969 at the University of Edinburgh.1,3±5 They showed that the polysaccharide of gum ghatti has an extremely complex structure. Complex arrays of neutral sugar units (Galp, Araf, Arap) and GluA are attached to a molecular core of alternating -D-GlucA and D-Man residues, the former linked though O-4 and the latter though O-2. The base structural units were identified using classical carbohydrate techniques. The aldobiouronic acid: -GlcA(1-2) D-Manp was first isolated as a product of the partial hydrolysis of damson and cherry gums and has subsequently been found to be a structural fragment of many plant gum polysaccharides. This unit is frequently found in the interior chains of these complex polysaccharides. It was found by partial hydrolysis of gum ghatti along

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with another aldobiuronic acid: 6-O-( -D-glucopyranosyluronic acid)-Dgalactose. In this study by Aspinall3 the longest oligosacchalride sequences found were: -D-Galp-{(1-6)- -D-Galp-}n(1-6)-D-Gal -D-Galp-{(1-6)- -D-Galp-}n(1-3)-L-Ara Smith degradation led to the isolation of a degraded gum from which 3-O-/3-D-galactopyranosyl-D-galactose, 6-O-/3-D-galactopyranosyl-Dgalactose (n = 0), 3-O-/3-D-galacto-pyranosyl-L-arabinose (n = 0), and 3-O-L-arabinopyranosyl-D-mannose were obtained on partial hydrolysis. These results imply that D-mannosyl residues are located in the interior of the molecular structure, and the following partial structure was proposed, in which this structural unit was found: ±(1!6)- -D-Galp-(1!6)- -D-Galp-(1!3)-L-Arap-(1!3)-D-Manp-l The chains of (1!6)-linked -D-galactopyranosyl residues are joined through an L-arabinopyranosyl `link' unit to a D-mannosyl residue in the basal chain. Subsequently, an acidic oligosaccharide (at first erroneously reported to be a trisaccharide) was characterised as the tetrasaccharide: O- -D-glucopyranosyluronic acid-(1!2)-O-D-mannopyranosyl-(1!4)-O -D-glucopyranosyluronic acid-(1!2)-D-mannose, and this provided evidence for the following sequence of the sugar residues in the inner chains. -D-GpA-(1!2)-D-Manp-(1!4)- -D-GpA-(1!2)-D-Man Based on these results the overall nature of the assembly was proposed.6 R R " " 6 6 ! 4)- -D-GlcA-(1!2)-D-Manp-(1!4)- -D-GlcA-(1!2)-D-Manp-(1 3 3 " " 1 1 L-Arap L-Arap 3 3 " " R0 R0 R = ÿ L-Araf- or L-Araf-(1!2, 3 or 5)-L-Araf-(1

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Handbook of hydrocolloids R0 =

# -D-GlcpA- " or (1 ! 6)-D-Galp -(1 3 n -D-Galp" R

The periodicity of the acidic groups in the main chain is an important feature and there are others scattered though the periphery. Also (1-3)- and (1-6)-linked Gal units make up associated side chains. This structure is further complicated by D-Man residues being present as double branch points. It is this molecular complexity that accounts for the quite spectacular rheological and solution properties of gum ghatti. It is the overall molecular shape arising from the periodicity of the chains which gives it a rod-like shape and accounts also for the chain entanglements which are a feature of systems of this gum in water.4 More recently further investigations of this gum using methylation and three successive, controlled Smith degradations confirmed the previous findings of Aspinall, and also showed that the side chains contained mainly 2-O- and 3-Osubstituted Araf units.2 A second Smith degradation eliminated the remaining Araf units, and their anomers became evident. The proportion of Galp units gradually increased in the form of non-reducing end and Galp units, although 3,6-di-O- and 3,4,6-tri-O-substituted Galp units diminished. After three degradations groups with consecutive 3-O-substituted -Galp units were formed. The proportion of periodate-resistant 3-O- and 2,3-di-O-substituted Manp units was maintained. These observations support the core nature of the Manp units and the linked 1-6 Gal chains. Rhamnose residues were located, which, although present in smaller amounts than the other sugars, are clearly observed in NMR studies. The study observed free -Araf-(1!2)-Araf and Araf-[ -Araf]n-Ara with n 4 and 7, which corresponds with 2-O- and 3-Osubstituted Araf side-chain structures in the polysaccharide, along with: -Rhap-(1 ! 4)-GlcpA, -Rhap-(1 ! 4)- -GlcpA-(1 ! 6)-Gal, and -Rhap-(1 ! 4)- -GlcpA-(1 ! 6)- -Galp-(1 ! 6)-Gal. On three successive, controlled Smith degradations, a product was formed with consecutive (1 ! 3)-linked -Galp units. One of the observations in NMR studies is of relevance to the difference in physical forms and heterogeneity which is a feature of this gum as collected from the forests in India. The variations in physical form and colour are not related to a basic difference in chemical composition or specific bonding since the spectra are essentially similar. Nevertheless, it is evident that much more is yet to be learnt about the structure of this remarkable gum.

Gum ghatti

17.4

483

Technical data

17.4.1 Solubility Gum ghatti occurs in nature as a calcium-magnesium salt and contains soluble and insoluble fractions which partially dissolve in boiling water. Gel fractions in ghatti have been reported which can be mostly dissolved by maceration; the gel fractions have a higher proportion of calcium ions.5 The gel is not primarily due to the presence of calcium ions and forms intermolecular linkages as a result.6 The viscosity of the gel dispersion was found to be ca. 10±30 times that of the soluble fraction and the gel fraction in commercial batches can vary from 8±23%.5±7 17.4.2 Physico-chemical parameters The quality of gum ghatti, like gum arabic, is also influenced by factors such as location, geographic climate and the form of the exudates (i.e. spiro, white or yellow nodules). The physico-chemical parameters for gum arabic and ghatti are compared in Table 17.1.8 The sample selected in Table 17.1 is a currently available gum ghatti called Shimla. The percentage loss on drying obtained for gum ghatti is similar to that of gum arabic in the lump gum form. While gum arabic is highly soluble in water, gum ghatti contains varying proportions of Table 17.1 Physico-chemical and molecular weight parameters of gum ghatti compared with gum arabic

% loss on drying % insoluble matter Specific optical rotation (deg dmÿ1 cm3 gÿ1) % galactose % arabinose % rhamonse % uronic acid % mannose % xylose % nitrogen % protein* Intrinsic viscosity ( cm3/g) in 1 M NaCl Intrinsic viscosity ( cm3/g) in 0.2 M NaCl Mw (whole gum) 105 Rg/nm (whole gum) Polydispersity (Mw/Mn) whole gum Mw (1st peak) 106 % mass 1st peak Rg/nm 1st peak Mw (2nd peak) 105 % mass (2nd peak) Rg/nm (2nd peak)

Gum arabic

Gum ghatti (shimla)

6.3 0 ÿ30 32.3 30.2 13.3 24.2 ÿ ÿ 0.314 2.1 16.8 18.3 6.22 29 2.36 2.54 10.6 41 3.96 89.4 ÿ

11.9 2.1 ÿ56.5 27.6 55.7 ÿ 11.7 3.3 1.6 0.518 3.4 52.7 64.4 8.7 35 1.35 1.87 21.2 45 5.9 79 22

*nitrogen conversion factor of 6.6 was used to calculate the protein %.

484


Table 17.2

Ala Arg Asp Cys Glu Gly His Hyp Ile Leu Lys Met Phe Pro Ser Thr Tyr Val

Amino acid composition (mol%) of gum arabic and gum ghatti Gum arabic

Gum ghatti

2.6 0.9 5.1 Ð 3.5 5.6 5.8 26.9 1.3 8.0 2.9 0.1 3.6 7.5 14.1 7.5 0.8 3.8

7.6 2.3 17.2 Ð 7.9 13.8 3.3 nd 3.9 5.4 9.2 0.3 2.3 6.9 4.7 5.1 2.4 7.7

insoluble gel. The ghatti sample used in this study was specifically supplied as highly soluble gum as demonstrated by the small percentage obtained for the insoluble matter (Table 17.1). One of the major differences between the two gums is the specific optical rotation (gum ghatti ÿ56.5ë, gum arabic ÿ30ë) and it is directly related to the difference in sugar composition. The presence of xylose and mannose are often used as a means of detecting its presence in formulations. For acacia gums it has been possible to relate the specific optical rotation to the vectorial contributions made by the individual sugars present.9,10 The second notable difference between the two gums is the protein content. The protein content of gum arabic is ~2% whereas gum ghatti has higher percentage at 3.4%. Gum ghatti contains a considerably higher percentage of Asp, Gly, Lys with lower percentages of Phe, Pro and Ser compared to gum arabic (Table 17.2). The intrinsic viscosity is a measure of hydrodynamic volume of macromolecules and the value obtained for gum ghatti is at least three times higher than that of gum arabic. This indicates that ghatti molecules are either highly solvated or asymmetric, or both when compared to gum arabic. Both gums contain uronic acid which confers a polyelectrolyte character as demonstrated by the increase in the overall size, due to electrostatic charge repulsion, while decreasing the ionic strength of the solvent (Table 17.1). 17.4.3 Molecular weight The structure and molecular weight of gum arabic have already been described11 and are summarised here in order to compare with gum ghatti. Hydrophobic fractionation of gum arabic has shown that it is a highly heterogeneous complex

Gum ghatti

485

polysaccharide which consists of three main fractions. These fractions are: arabinogalactan protein complex (AGP), arabinogalactan (AG) and glycoprotein (GP). Each fraction contains an average of different molecular weight components with different protein content. One of the proposed models for the AGP fraction suggests that it is composed of hydrophilic carbohydrate blocks linked to a protein chain and has been reported to have a wattle blossom-type structure due to being readily degraded by proteolytic enzyme.12,13 Other models to describe the structure of the AGP fraction have been recently reviewed.14 Gel permeation chromatography coupled on line to a multi-angle laser scattering, refractive index and UV detectors (GPC-MALLS) is now routinely used to identify the components in gum arabic, as labelled in Fig. 17.2(a).8,15,16 The same method was applied for the fractionation gum ghatti and the elution profile is shown in Fig. 17.2(b). The light scattering response shows the presence of two peaks with partial separation of the second peak, which appears as a shoulder. The RI response also shows the presence of these two peaks and the first peak coincided with the light scattering response, whereas the second peak

Fig. 17.2 Elution profile of (a) gum arabic and (b) gum ghatti following fractionation by gel permeation chromatography and detection by light scattering, refractive index and UV detectors.

486


was lower than the first peak and contained the majority of the gum. The UV response showed that there is protein associated with the high molecular weight materials and the second peak also appears as shoulder and follows the same RI response. The UV response shows a third low molecular weight peak which elutes at ~15±18.5 ml before the total volume of the column (~20 ml). The molecular weight parameters of the whole gum and when processed as two peaks are given in Table 17.1 and compared with gum arabic. The weight average molecular weight (Mw) and root mean square radius of gyration (Rg) of gum ghatti is higher than that of standard gum arabic but is less polydisperse. The Mw and Rg of the first peak in gum ghatti, known as the AGP fraction in gum arabic, is comparable but in ghatti gum with double the concentration. The molecular weight parameters of the second peak are also higher but with slightly lower amounts compared to gum arabic. A third proteinaceous peak with high UV absorption was also identified in gum ghatti (Fig. 17.2(b)) but was difficult to accurately determine its molecular weight due to very low light scattering response. However, integration of the area under the peak for a range of ghatti samples revealed that the proportion of this peak is ~1±2.2% of the whole gum. The proportion of the third for the sample shown in Fig. 17.2(b) was 1.38% of the total injected mass. The total mass recovery for gum ghatti was 102% which indicates a suitability of column used for the fractionation and in agreement with the solubility determined independently using the weight of the materials retained on the filter (Table 17.1). 17.4.4 Rheology The viscosity of gum ghatti, like other hydrocolloids, increases exponentially with increasing concentration. Gum ghatti makes a viscous solution at 30±35 wt% (Fig. 17.3). Rheological measurements showing the shear flow viscosity of gum arabic and gum ghatti as a function of shear rate are shown in Fig. 17.3 (inset). At relatively diluted concentration (5% ghatti and 10% gum arabic) both show evidence of shear thinning behaviour at low shear rates and were Newtonian at higher shear rates. However, the viscosity of gum ghatti is double that of gum arabic as demonstrated by the almost exact viscosity match between the two gums. With increasing the concentration (45% gum arabic, 30% gum ghatti), both gums show a clear shear thinning behaviour albeit at different shear rates. The viscosity difference between the two gums is largely explained by the higher intrinsic viscosity and proportion of high molecular weight present in gum ghatti compared to gum arabic (Table 17.1 and Fig. 17.2). 17.4.5 Emulsification The emulsification performance of gum ghatti is greatly influenced by the presence of insoluble components. These insoluble components are usually filtered and removed during the manufacture of beverage emulsion. Gum ghatti, like other hydrocolloid emulsifiers, such as gum arabic and sugar beet pectin, contain a small amount of protein linked to the carbohydrate unit. Enzyme

Gum ghatti

487

Fig. 17.3 Viscosity of gum ghatti as a function of concentration. (Inset) Shear flow viscosity plotted as a function of shear rate for (ú) 10% w/w, ( ) 45% w/w gum arabic and (n) 5%, (l) 30% w/w gum ghatti. Solutions were dissolved in distilled water containing 0.005% w/v NaN3. All measurements were carried out at 25 ëC.

digestion with protease does not greatly reduce the molecular weight. However, when the gum is subjected to processing, such as spray drying, the effect of enzyme digestion can be clearly seen as results of changes in the protein conformation which then become more accessible. Further evidence of protein± carbohydrate linkage is supported by the interaction with Yariv's reagent and hence can be classified as arabinogalactan-protein complex. The emulsification mechanism in gum ghatti is similar to that of gum arabic where the protein is responsible for the surface activity by acting as the strong anchor point at the oil±water interface with the hydrophilic polysaccharide chains providing the protective layer.17 This is why gum ghatti can emulsify 20% medium chain triglyceride (MCT) oil at much lower concentration (5 wt%) compared to gum arabic as shown in Fig. 17.4. In Fig. 17.4 the emulsification performance and stability of gum ghatti, which is completely soluble, is compared with standard gum arabic at a range of concentrations. The interfacial rheology of gum ghatti is superior to that of gum arabic at the same concentration due to the high protein content and possibly the conformation in solution. Additionally, gum ghatti is more resistant to heat and this is clearly reflected by the emulsion stability following acceleration at 60 ëC for 3 days. Detailed evaluation of emulsification performance of gum ghatti has recently been reported.18

17.5


Gum ghatti has an age-old reputation in India as being a very good medicinal product as well as having very good qualities for food products. This gum has been mentioned in ancient medicinal scriptures like the Ayurveda (Indian system

488


Fig. 17.4 Volume weighted mean (d[4,3]) for initial and accelerated emulsions of gum arabic (5±20 wt%) and gum ghatti at 5 wt%. Oil phase 20% MCT, 0.12% citric acid, 0.13% sodium benzoate.

of medicine) and the Unani (Greek system of medicine). In some parts of India, the clean nodules of a variety of ghatti called Spiro, are eaten as a luxury product and are considered a sign of wealth and prosperity. It has been used throughout households and industry as a good adhesive. Other uses include hair gel, print industry in India particularly screen printing, confectionary and by the petroleum industry as a drilling mud conditioner. The newly processed gum ghatti (GATIFOLIA SD) gives a solution of moderate viscosity which falls between gum arabic and gum karaya. By utilising the excellent emulsifying properties and the complete solubility of GATIFOLIA SD it has been possible to show that it can be used in many emulsified products as an emulsifier in formulations which are difficult to stabilise using gum arabic. Examples of various formulations are given below. 17.5.1

Beverage emulsion

Formulation 17.1 Ingredients Oil (MCT) Gum ghatti Citric acid Benzoate Ion exchange water

MCT % 20 5 0.12 0.13 to 100

Gum ghatti

489

Preparation The emulsion is prepared using Nanomiser (Laboratory scale high pressure homogeniser, Yoshida Kikai Co., Ltd) at 50 MPa, 2 passes. Formulation 17.2

Orange oil±ester gum

Ingredients

%

Oil Orange oil Ester gum Gum ghatti (GHATIFOLIA) Citric acid Benzoate Ion exchange water

14 7 7 5 0.2 0.1 to 100

Preparation 1. The oil phase is prepared by mixing ester gum and orange oil at 1:1 ratio. 2. The oil phase is then added to the aqueous phase, containing citric acid and sodium benzoate. 3. The emulsion is prepared using Nanomiser (Laboratory scale high pressure homogeniser, Yoshida Kikai Co., Ltd) at 50 MPa, 2 passes. Formulation 17.3

Orange oil, ester gum, -carotene, MCT

Ingredients Oil Orange oil Ester gum MCT -carotene Gum ghatti (GHATIFOLIA SD) Citric acid Benzoate Ion exchange water

% 14 4 4 4 2 5 0.2 0.1 to 100

Preparation 1. The oil phase is prepared by mixing ester gum and orange oil at 1:1 ratio. 2. The oil phase is then added to the aqueous phase, containing citric acid and sodium benzoate, followed by the addition of MCT. 3. The emulsion is homogenised using Nanomiser (Laboratory scale high pressure homogeniser, Yoshida Kikai Co., Ltd) at 50 MPa, 2 passes.

17.5.2

Mayonnaise type dressing (70% fat)

Formulation 17.4 Ingredients 1. Corn oil 2. Vinegar

% 70 4.5

490 3. 4. 5. 6. 7. 8. 9. 10.


Apple vinegar Lemon fruit juice Gum ghatti (GHATIFOLIA SD) SAN ACE Sugar Salt Sodium glutaminate Ion exchange water

7.0 2.0 2.0 0.15 1.0 2.5 0.1 to 100

Note: typical emulsifier used in the above formulation is egg white at 10%. Preparation 1. Slowly add ingredients 5±9 into water while stirring. 2. Add ingredients 2±4 and continue stirring the blend. 3. Add egg yolk at the end of this step. 4. Slowly add oil and stir blend. 5. Emulsify using a colloid mill.

17.5.3

Dressings (30% fat)

Formulation 17.5 Ingredients 1. 2. 3. 4. 5. 6. 7. 8.

Corn oil Vinegar Gum ghatti (GHATIFOLIA SD) SAN ACE Sugar Salt Sodium glutaminate Ion exchange water

% 30 5.3 0.1 0.2 3.0 5.0 0.4 to 100

Note: typical emulsifier used in the above formulation is egg white at 0.5%. Preparation 1. Slowly add ingredients 5±7 into water while stirring. 2. Add ingredients 2±4 and stir blend. 3. Slowly add oil and stir blend. 4. Emulsify using a colloid mill or homo-mixer.

17.5.4

Butter cream

Formulation 17.6 Ingredients

%

Shortening Margarine Sugar syrup GATIFOLIA SD

30 25 20 0.2

Gum ghatti Milk flavour No. 71005 Carotene base No. 80

491

0.2 0.02

Preparation 1. Slowly add GATIFOLIA SD into sugar syrup while stirring the blend. 2. Add flavour and carotene into the syrup and stir blend. 3. Add the syrup into shortening/margarine mixture and stir blend.

17.6

Regulatory status

South America Argentina, Bolivia, Chile and Peru: Not permitted Brazil: Permitted as an emulsifier to aid homogenising flavours or to incorporate them in food products. No maximum level specified. Colombia: Permitted as a natural emulsifier in foodstuffs. Ecuador: Permitted as a natural emulsifier, stabiliser and thickener. Guatemala: Permitted in food as emulsifier, stabiliser and thickener. Maximum level in soft drink and non-alcoholic beverages specified at 0.2%. Mexico: Permitted in all foods as a natural emulsifier, stabiliser, thickener and gelling agent. Uruguay: Permitted as an emulsifier for flavours with no maximum level specified. Venezuela: Permitted as a natural emulsifier, stabiliser and thickener. No maximum level specified for carbonated beverages and sweets. Instant drink powder should not exceed 0.1%. Asia China: Permitted in food as an emulsifier for flavours. No maximum level specified (an appropriate amount as practically needed). India: Bureau of Indian Standards (BIS) ± IS 7239:1974 (Food Grade) Permitted in food as a natural emulsifier, stabiliser and thickener as detailed below: · Stabiliser and emulsifier in sugar-boiled confectionery, processed cheese spread with no maximum level set. · Emulsifier in chewing gum, bubble gum, malted milk food with no maximum level set. · Stabiliser in yoghurt, milk ices and milk lollies with maximum level set at 0.5%. · Emulsifier and/or stabiliser in ice candy, ice cream, kulfi, chocolate ice cream, ice lollies or edible ices with maximum level set at 0.5%. · Emulsifier, stabiliser and thickener in frozen desserts with no maximum level set. · Emulsifier, stabiliser and thickener in fat spread table margarine, bakery and industrial margarine, wafer biscuits and flavouring agent with no maximum level set.

492


South Korea: Permitted in all foods (unless specifically prohibited for use in a compositional standard) as natural food additives with no specific function defined. Singapore: Permitted in all foods (unless specifically prohibited for use in a compositional standard and in unstandardised foods) as natural emulsifier and stabilizer with no specific function defined. United States Permitted in food as an emulsifier, emulsifier salt in · Beverages and beverage bases, non-alcoholic with a maximum level set at 0.2%. All other food categories at a maximum level of 0.1%. The following regulations are relevant to the use of gum ghatti in the United States. · Code of Federal Regulations(CFR), Food and Drug Administration, Department of Health and Human Services CFR ± Title 21, Code ± 184.1333 · The Flavor and Extract Manufacturers Association FEMA ± GRAS status, Limitation ± Stabilizer · Chemical Abstracts Service CAS ± 009000-28-6 · Priority Based Assessment of Food Additives PAFA ± 2149 · Registry of Toxic Effects of Chemical Substances RTECS ± LY8935000 Japan Permitted in all foods as natural food additives with no specific function defined and subject to the following specification: · Identification test 1: When 1 g is dispersed in 5 ml of water it forms a viscous, adhesive mucilage. · Identification test 2: To 5 ml of 1 in 100 solution of the sample (filter through diatomaceous earth if necessary) add 0.2 ml of dilute lead subacetate TS. A small or no precipitate is formed, but an opaque flocculent precipitate is produced upon the further addition of 0.5 ml of ammonia TS. · Identification test 3: A 1 in 50 solution of the sample filtered through diatomaceous earth is levorotatory. · Heavy metals: Not more than 4 ppm. · Lead: Not more than 10 ppm. · Arsenic (as As2O3): Not more than 4 ppm. · Loss on drying (105 ëC, 5 hours): Not more than 14%. · Ash content: Not more than 6%. · Acid insoluble ash: Not more than 1%. · Viable bacteria: Not more than 10,000/g. · Escherichia coli: Negative. Europe Not permitted.

Gum ghatti

493

Russia Permitted as stabiliser, thickener and gelling agent. Not defined for particular oodstuff and no maximum level set. South Africa Permitted as an emulsifier in condiments and sauces, soft drinks, breakfast cereals, flour confectionery and cakes mixes with no maximum level set. Australia Gum ghatti falls under the list of approved herbs.

17.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.

References

ASPINALL GO, BHAVANADAN VP, CHRISTENSEN TB

Chem. Soc., 2677±2684.

(1965) `Gum ghatti (Indian gum)', J.

et al. (2002) `New structural features of the polysaccharide from gum ghatti (Anogeissus latifola)', Carbohydrate Research, 337: 2205±2210. ASPINALL GO (1980) `Chemistry of cell wall polysaccharides', in The Biochemistry of Plants (vol 3), Preiss J (ed.), Academic Press, New York, pp. 473±500. ELWORTHY PH, GEORGE TM (1963) `The molecular properties of ghatti gum: A naturally occuring polyelectrolyte', J Pharm. Pharmacol., 15: 781±793. JEFFERIES M, PASS G, PHILLIPS GO (1977) `Viscosity of aqueous solutions of gum ghatti', J. Sci. Food Agric., 28: 173±179. JEFFERIES M, PASS G, PHILLIPS GO, ZAKARIA MB (1978) Èffect of metal-ion content on viscosity of gum ghatti', J. Sci. Food Agric., 29: 193±200. JEFFERIES M, KONADU EY, PASS G (1982) `Cation effects on the viscosity of gum ghatti', J. Sci. Food Agric., 33: 1152±1159. AL-ASSAF S, PHILLIPS GO, WILLIAMS PA (2005) `Studies on acacia exudate gums. Part I: the molecular weight of Acacia senegal gum exudate', Food Hydrocolloids, 19: 647±660. BISWAS B, BISWAS S, PHILLIPS GO (2000) `The relationship of specific optical rotation to structural composition for Acacia and related gums', Food Hydrocolloids, 14: 601±608. BISWAS B, PHILLIPS GO (2003) `Computation of specific optical rotation from carbohydrate composition of exudate gums Acacia senegal and Acacia seyal', Food Hydrocolloids, 17: 177±189. WILLIAMS PA, PHILLIPS GO (2000) `Gum arabic', in Handbook of Hydrocolloids, Phillips GO, Williams PA (eds), CRC Press, Cambridge, pp. 155±168. OSMAN ME, MENZIES AR, WILLIAMS PA, PHILLIPS GO, BALDWIN TC (1993) `The molecular characterization of the polysaccharide gum from Acacia senegal', Carbohydrate Research, 246: 303±318. CONNOLLY S, FENYO JC, VANDEVELDE MC (1987) `The effect of pronase on the aminoacid composition of gum arabic', Comptes Rendus des Seances de la SocieÂteÂ de Biologie et de ses Filiales, 181: 683±687. WILLIAMS PA, PHILLIPS GO, STEPHEN AM, CHURMS SC (2006) `Gums and Mucilages', in TISCHER CA, IACOMINI M, WAGNER R,

494

15.

16.

17. 18.

Handbook of hydrocolloids Foood Polysaccharides and Their Complexes, 2nd edn, Stephen AM, Williams PA (eds), Taylor & Francis, London, pp. 455±495. AL-ASSAF S, PHILLIPS GO, AOKI H, SASAKI Y (2007) `Characterization and properties of Acacia senegal (L.) Willd. var. senegal with enhanced properties (Acacia (sen) SUPER GUM (TM)): Part 1 ± Controlled maturation of Acacia senegal var. senegal to increase viscoelasticity, produce a hydrogel form and convert a poor into a good emulsifier', Food Hydrocolloids, 21: 319±328. AOKI H, AL-ASSAF S, KATAYAMA T, PHILLIPS GO (2007) `Characterization and properties of Acacia senegal (L.) Willd. var. senegal with enhanced properties (Acacia (sen) SUPER GUM (TM)): Part 2 ± Mechanism of the maturation process', Food Hydrocolloids, 21: 329±337. DICKINSON E (2003) `Hydrocolloids at interfaces and the influence on the properties of dispersed systems', Food Hydrocolloids, 17: 25±39. AL-ASSAF S, AMAR V, PHILLIPS GO (2008) Characterisation of gum ghatti and comparison with gum arabic, in Gums and Stabilisers for the Food Industry 14, Williams PA, Phillips GO (eds), Wrexham, Royal Society of Chemistry, pp. 280± 290.

18 Other exudates: tragancanth, karaya, mesquite gum and larchwood arabinogalactan Y. LoÂpez-Franco and I. Higuera-Ciapara, Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo, Mexico, F. M. Goycoolea, Universidad de Santiago de Compostela, Spain and Centro de InvestigacioÂn en AlimentacioÂn y Desarrollo, Mexico and W. Wang, Andi-Johnson Konjac C. Ltd., China

Abstract: The collection, processing and trading of plant exudate gums, other than gum arabic, and the production of arabinogalactan from the heartwood of Western larch tree represent an important economic activity in many regions of the world. What this family of materials shares in common is that they are comprised of highly branched heteropolysaccharide structures. This chapter addresses the manufacture, chemical structure, functional properties, main applications and regulatory issues for three wellestablished hydrocolloids, namely gum tragacanth, gum karaya and larchwood arabinogalactan along with those of mesquite gum, whose full potential utilization is still to be exploited in several fields of application. Key words: gum tragacanth, gum karaya, mesquite gum, larchwood arabinogalactan, exudates.

18.1

Introduction

Although gum arabic is by far the most important plant exudate hydrocolloid, there are other related gums that have retained their economic and technological importance for centuries despite the availability of several new alternative industrial hydrocolloids. In fact, natural plant gums are the most widely used and traded non-wood forest products other than items consumed directly as food, fodder and medicine (Upadhayay, 2006). Their collection by hand still

496


represents a source of income for millions of people, dwelling in rural areas mostly in Africa, India, Iran, Turkey, and to a less extent, in Mexico. In northern USA, the extraction of arabinogalactan from larch trees also represents an important economic activity. Gums are exuded by the bark of trees in the form of tear-like, striated nodules or amorphous lumps, which are vitrified upon drying, thus forming hard, glassy lumps (gum karaya and mesquite gum) or tough opaque thin ribbons (gum tragacanth) of different colours, ranging from red-amber for mesquite gum, pale gray to dark brown for karaya gum, and white to dark brown for tragacanth. In general, the gums are produced by the stem under conditions of heat and drought stress, partly as a natural phenomenon (as part of the normal metabolism of plants) and partly as a result of injury to the bark or stem (due to fungal or bacterial attack) by a process known as gummosis. The other type of polysaccharide gum addressed in this chapter is not strictly an exudate like the others, but it is extracted from the vacuoles of the heartwood of the Western larch tree and related species. Chemically, these materials are known to be comprised to varying extents either by arabinogalactan (AG) heteropolysaccharides (e.g., larchwood arabinogalactan) or occur as complex mixtures of other acetylated polysaccharides such as rhamnogalacturonan (e.g., gum karaya); mixtures of galacturonan regions and type II AG as gum tragacanth (Verbeken et al., 2003) or macromolecular complexes of type II AG and proteoglycans (arabinogalactan-protein, AGP) comprising ca. 4% of protein such as mesquite gum (Goycoolea et al., 2000). As a consequence of this chemical structural diversity, these polysaccharides exhibit very different functional properties and thus they have found applications in various fields. The individual properties of gum tragacanth, gum karaya, mesquite gum and larch arabinogalactan are discussed throughout the various sections of this chapter.

18.2

Manufacture

18.2.1 Gum tragacanth Gum tragacanth was first described by Theophrastus several centuries before Christ. The name tragacanth, from the Greek tragos (goat) and akantha (horn), probably refers to the curved shape of the ribbons, the best grade of commercial gum. The gum is obtained from small shrubs of the Astragalus genus, comprising up to 2000 species indigenous to mountain areas of south west Asia from Pakistan to Greece (Whistler, 1993). A. gummifer was considered to be the main tragacanth yielding species, but a field survey established that A. microcephalus was the principal source of the gum (Dogan et al., 1985); A. kurdicus and A. gossypinus have also been documented as botanical sources. The plants are small, low bushy perennial shrubs having a large tap root along with branches. The root and lower stem are tapped for gum.

Other exudates

497

The main areas of commercial production are the arid and mountainous regions of Iran (accounting for ~70% of the supplies) and the Anatolia region in Turkey (Anderson, 1989), and in lesser amounts in Afghanistan and Syria. In the past, several thousand tonnes of tragacanth were used in food, pharmaceutical and technical applications. However, as a result of very high costs, erratic supply and strong competition from xanthan gum, demand for the gum fell dramatically from several thousand to 200±300 tonnes per year (Anderson, 1989). Iran's recovery in the gum tragacanth export market suggests that, with a correct understanding of the world market and supply of premium product, there is a vast prospect for a bigger and better market for this gum. Trade sources in London have quote prices (mid-1995) at around US$22/kg free on board (FOB) for the top grade (Ribbon no. 1), US$16/kg for Ribbon no. 4 and falling to US$3±4/kg for the lowest grades. Current quoted price for gum from Azerbaijan is US$30/kg. Plants develop a mass of gum in the centre of the root, which swells in the summer heat. If the stem is slit, soft gum is exuded. The exudate is produced spontaneously on the bark of the shrub, but both the yield and quality are often increased by making incisions in the tap root and lower stem. Abundant rainfall prior to the tapping season, and dry conditions during the harvesting season, constitute optimum climate conditions for gum production. Tapping is carried out in May or June with subsequent collection in August and September (after 6 weeks) for ribbon grades and August to November for Flake grades (Wareing, 1997). The gum is obtained in two basic physical forms, namely ribbons (superior quality) and flakes (inferior quality). These two forms are obtained from different sub-species of the shrub. Both types of shrubs normally do not grow in the same locality (Robbins, 1988). After collection, the gum is sorted by hand by the natives and carried to sorting centres where it is graded into several grades of ribbons and flakes and exported. The Iranian grading system is more clearly defined than that of Turkey and comprises nine different grades. The most commonly used Iranian qualities are ribbons 1 and 4, mixed ribbon and flakes 27, 28 and 55, while in Turkey there are four grades, namely, Fior Extra and Fior for ribbons and Bianca and Pianto for flakes. The best qualities are regarded as those with higher viscosity, good solution colour and low microbiological limits. Blending is necessary to ensure the desired properties. Processors in the US and Europe purchase material following approval of pre-delivery samples. Quality control inspections of each incoming batch are necessary to ensure powder blends meet well-defined specifications for powder and solution colour and viscosity. Food applications for sauces, dressings, icings, and confectionery normally use mixed ribbon or flake grades. Lower qualities are used where solution colour is less important and where thermal processing, pH and/or the soluble solids level are sufficient to prevent microbial proliferation in the final product. Limited mechanical treatment to remove foreign matter may be carried out in the exporting countries but no further processing is undertaken. Importers in the US and Western Europe, primarily in the UK and Germany, ensure consistent

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quality standards are maintained for the powdered material after milling. The best ribbon grades have low total viable counts of bacteria comprising mainly resistant spores from the soil and airbone contamination. These problems were previously controlled through fumigation with ethylene oxide (ETO). This process was forbidden around 1987 in the treatment of gum destined for food uses, because of carcinogenicity of ETO. The alternative methods of bringing down the microbial counts also cause chemical changes in the gum and accordingly are not acceptable (Anderson and Weiping, 1994). In the US propylene oxide is allowed but its efficacy is limited and permission for its use may be revoked. 18.2.2 Gum karaya Karaya gum, also known as sterculia gum, is the dry exudate of Sterculia urens (Roxburgh), a large and bushy tree. The majority of commercial material is obtained from wild S. urens trees, indigenous to central and northern India and more than half of the gum is produced in the state of Andhra Pradesh. Other significant sources are from S. setigera, in Senegal and Mali, and minor supplies from S. villosa in Sudan, India and Pakistan. The history of gum karaya trading, in contrast to tragacanth, is quite recent. It goes back to the 1920s when the gum used to be sold as an adulterant to tragacanth. World production and usage is currently 1500 tonnes per year. The major users of gum karaya are the US, France and the UK. Minor quantities are imported into Japan, Belgium, Germany and other European countries (Robbins, 1988). The export of Indian gum karaya declined from 4000 tonnes in 1982 to 1000 tonnes in 1992 and has remained roughly constant up to 2002, mostly due to a sharp decrease in the number of trees available for tapping due to unsustainable harvesting methods (Upadhayay, 2006). Over the past two decades, the prices in India have risen as a consequence of the increase in demand and shortage in production. In turn, exports from Senegal and other countries increased their production in the late 1980s to 1500 tonnes per annum and this has resulted in more competition and more stable prices. Indicative FOB prices quoted by importers in London for Indian karaya (mid-1995) are in the range US$2250± 6000/tonne according to grade. Fair average quality (FAQ) gum is about US$3000/tonne. For production, the trees are incised or tapped and exudation begins immediately and continues for several days forming irregular lumps (or tears) which may weigh more than 1 kg, and large trees can produce up to 4.5 kg (Whistler, 1993). The exudate is allowed to dry on the tree and is later collected, broken, cleaned and sorted. The highest quality of raw gum collected is during the hot months of April, May and June. In September, the gum is again picked. This autumn crop has a greyish colour and is normally less viscous. The gum is cleaned to remove bark and foreign matter (BFM) before sorting. Commercially available quality grades are hand-picked selected (HPS), superior no. 1, no. 2 and no. 3 (FAQ), and siftings (Verbeken et al., 2003). BFM can be found in

Other exudates

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white to very light tan HPS and superior no. 1 grades in proportions of 0±0.5% and 1.0±2.0%, respectively; 1.5±3.5% in very light tan superior no. 2; 2.5±4.0% in tan FAQ gum and 5.0±7.0% in the brown colour siftings (Wareing, 1997). Gum karaya is processed to remove impurities such as bark, stones, fibres and sand. It is then milled, blended and classified according to mesh, viscosity and purity. The gum is offered as granules or in powder form. The granule size ranges from 4±8 mesh and 8±14 mesh and powder size is 160 mesh with viscosity ranging from 500±1200 cps. The powder is light to pinkish gray and has a slight acetic taste and odour. The microbial quality of this gum is similar to that of other exudates, and its use in sauces and dressings is safe, as the low pH of these products and the heat treatments they are regularly subjected to are sufficient to ensure safety. 18.2.3 Mesquite gum Mesquite trees are leguminous plant trees that are widespread in arid and semiarid regions of the world and account for one of the major plant species in such places. In fact, the genus Prosopis comprises about 44 different species that grow mostly in North and South America, and also in Australia, Africa, and eastern Asia. In Mexico, around ten species are found, of which the most abundant is P. juliflora (Vernon-Carter et al., 2000), which has also been suggested to correspond with P. laevigata. This species grows from the coastal areas of the Pacific Ocean in the Mexican state of Sinaloa to Panama, in the centre and south of Mexico, reaching all the way to the south-eastern United States under environmental conditions that range from subhumid to areas with an average rainfall of up to 1500 mm. It is well documented that the bark of Prosopis spp. produces an exudate known as mesquite gum as a response to insect attack, wounding or physiological stresses such as severe water and heat. The gum could be defined as `the dried gummy exudation obtained from the stems and branches of Prosopis species'. By contrast with commercial gum arabic, karaya and tragacanth gums, mesquite exudate is not an established hydrocolloid in the world market. However, the gum was widely used by the Indian cultures of the Mexican Northwest (Seri and Yaqui) and southwestern United States (Papago and Pima) (Felger, 1977), mainly as a sweet and as a medicinal aid to prepare eye drops (Felger and Moser, 1974). Presently, mesquite gum, known in Sonora as chuÂcata, is used in few household applications. However, in the past, mesquite gum has been used extensively in food applications and has been traditionally considered as a `substitute or adulterant of gum arabic, of inferior quality due to its darker colour' (Smith and Montgomery, 1959). In Mexico, there are two main regions where mesquite gum is produced, namely, in the desert plains of the northwestern state of Sonora, where the predominant source is P. velutina and in the lowlands of the Northeastern state of San Luis Potosi, where the gum is sourced mostly from P. laevigata. The structural and functional properties of mesquite gum have been studied extensively mostly by two independent

500


Mexican research groups, namely, the group led by Dr J. Vernon-Carter, at Universidad AutoÂnoma Metropolitana, that has worked with the gum from San Luis Potosi, and our group that has worked with the material from Sonora. The production season of mesquite gum in Sonora begins during the late spring and early summer months (May±July), ending with the summer rains at late July/early August. At present, the collection of mesquite gum is not properly organized and there is not a quality grading system to sort it. Nevertheless, as with other gum exudates, the nodules can be classified by size, colour and by the contents of bark and foreign matter. In some cases dark gum nodules are eliminated by their high tannin content depending on their intended use (OrozcoVillafuerte et al., 2000). Ultrafiltration studies in mesquite gum from Sonora showed that this technology was feasible to reduce the contents of naturally occurring tannin compounds (Goycoolea et al., 1998). Quantitative analysis of the removed tannins indicated that up to ~62% of the original tannin contents can be removed using a hollow fibre membrane of 10 kDa molecular weight cutoff without compromising the emulsification capacity of mesquite gum. The only information available on production of mesquite gum from wild plantations comes from a few field studies that have tried to estimate the availability of the gum in the two collection regions in Mexico. In San Luis Potosi, it has been estimated that the potential production in an area of 600 km2 is ~2000 tonnes p.a. (Vernon-Carter et al., 2000), while in Sonora the estimated total annual production was nearly half as much, at ~800 tonnes (Goycoolea et al., 2000). These figures allow us to conclude that the potential production of mesquite gum from wild mesquite forests could fulfil the 2004 demand for gum arabic which was in the order of ~1417 tonnes (SecretarõÂa de EconomõÂa, 2004). Unfortunately, to date mesquite gum is neither produced on a large scale, nor are there commercial plantations, extraction methods or efficient collection systems. Besides, the price at which gum arabic is currently imported to Mexico at ~$US3200/tonne (SecretarõÂa de EconomõÂa, 2005) renders it economically unfeasible to collect mesquite gum from the wild areas. In light of the above, alternative production methods have been investigated. In vitro studies for culturing of P. laevigata and laboratory conditions for the gum production by stem segments (Orozco-Villafuerte et al., 2000) have demonstrated that application of combined environmental conditions (temperature increase) and biotic elicitors, can be utilized for increasing mesquite gum production with similar characteristics to those produced in situ by wild trees (Orozco-Villafuerte et al., 2005). 18.2.4 Larchwood arabinogalactan Arabinogalactan is particularly abundant in larchwood (genus Larix) and especially in Western larch (Larix occidentalis) from whose heartwood AG can be extracted in high yield (Stephen, 1983). Extraction of water-soluble arabinogalactan from shavings of the butt of the Western larch tree was first described in 1898 (Trimble, 1898), though no quantitative data was reported.

Other exudates

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During the twentieth century this material continued to receive economic and scientific interest and later it was found that arabinose and galactose were its main constituents (Wise and Peterson, 1930; Nikitin and Soloviev, 1935). Subsequent efforts at large-scale commercialization were hampered by the economics of extraction and purification (Anderson, 1967). However, technological improvements were made and presently larchwood arabinogalactan is produced on an industrial scale and its market developed as food fibre and for biomedical and healthcare applications (Gallez et al., 1994). The most practical method of extraction consists of hot water treatment using countercurrent flow of the drilled or chipped heartwood (Adams and Ettling, 1973) from Dahurian larch (Larix dadurica), Siberian larch (Larix siberica), Eastern larch (Larix laricina), European larch (Larix deciduas), Japanese larch (Larix leptolepsis) and Western larch tree (Larix occidentalis), which contains quantities up to 35% of the arabinogalactan in vacuoles and it is the most abundant and available source (Stephen and Churms, 1995). Arabinogalactan is available commercially in ultrafiltered (AG±UF) and in food grades (AG±FG) (Christian et al., 1998). Conditions used to isolate arabinogalactan from L. occidentalis include extraction at 70 ëC for several days and use of magnesium oxide (Adams and Ettling, 1973). The Swiss company Lonza Inc. (which has recently acquired Larex Inc.), is presently the major manufacturer of larch arabinogalactan for commercial applications in the world, including medicinal and food supplements. The company owns patents on composition and extraction processes for a range of AG products of varying qualities, depending on the application fields they are intended for. Their industrial facility has a production capacity for 3.7 million metric tonnes (dry weight) of arabinogalactan. The amount of arabinogalactan that could be obtained from 1% of larch trees each year in the United States is 4.6 million metric tonnes. The intellectual property of the processes to produce this gum from larch trees is covered under various patents (DeWitt, 1989; Adams and Knudson, 1990; Price et al., 1995).

18.3

Structure

18.3.1 Gum tragacanth The structures of polysaccharides of gum tragacanth were investigated in detail by James and Smith (1945a, 1945b) followed by Aspinall and Baillie (1963a, 1963b). The gum is a slightly acidic salt occurring naturally with calcium, magnesium and sodium cations (Whistler, 1993). Gum tragacanth has a molecular weight of about 840 kDa, calculated by Svedberg's method and formula and an elongated shape of 450 nm by 1.9 nm, providing a high viscosity. Astragalus species (A. gummifer, A. microcephalus and A. kurdicus) have 1± 3.6% of protein with the proportions of the major amino acid constituents (Asp, Hyp, Ser, Pro and Val) also varying (Whistler, 1993; Stephen and Churms, 1995).

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Gum tragacanth is composed of two major components: tragacanthic acid and a small amount of a water soluble arabinogalactan and the bassorin fraction which is insoluble but swells in water to form a gel. The water soluble tragacanthin, accounts for 30±40% of the gum and is reported as a neutral, highly branched arabinogalactan (of type II) comprising (1!6)- and (1!3)linked core chain containing galactose and arabinose (both in furanose and pyranose forms) and side groups of (1!2)-, (1!3)- and (1!5)-linked arabinose units occurring as monosccharide or oligosaccharides (Stephen and Churms, 1995; Tischer et al., 2002). Acid hydrolysis revealed that tragacanthin (Astralagus gummifer) contains neutral monosaccharides such as L-fucose (LFuc), L-(L-Ara), D-xylose (D-Xyl), D-mannose (D-Man), D-galactose (D-Gal) and D-glucose (D-Glc) in a 3:52:29:6:5:5 molar ratio and the arabinogalactan contained L-rhamnose (L-Rha), L-Fuc, L-Ara, D-Xyl, D-Man, D-Gal and D-Glc in a 1:1:68:2:5:22:1 molar ratio (Tisher et al., 2002). This polysaccharide component is soluble in a mixture of ethanol-water (7:3). Recently, intrinsic viscosity [], molecular weight MW, and radius of gyration hS 2 iz1=2 of tragacanthin from Astragalus gossypinus were calculated to be, [] 9.077 10±3 MW0.87 (mL g±1), hS 2 iz1=2 0:021 MW0.59 (nm) in the range of MW from 1.8 105 to 1.6 106. The conformational parameter of tragacanthin were 1111 g mol for molar mass per unit contour length (ML), 26 nm for persistence length (q) and 1.87 ratio of RGRH (Mohammadifar et al., 2006). Bassorin, a pectic component (Fig. 18.1), has a chain of (1!4)-linked -Dgalacturonic acid units some of which are substituted at O-3 with -Dxylopyranosyl units and some of these being terminated with D-Gal or L-Fuc. Bassorin appears to contain some methyl groups. It was reported that for most species of Astragalus, the insoluble part has less methoxyl and galacturonic acid than the soluble part. Pectic component is dissolved partly in dilute aqueous sodium hydroxide. Grade precipitation of alkali soluble material gave fractions similar to those isolated from the water-soluble proportion of the gum. Bassorin and tragacanthin have quite different rheological properties: while 1% bassorin solution at 25 ëC shows a high viscosity gel-like structure, tragacanthin solution behaves like semi-dilute to concentrated solution of entangled, random coil polymers (Mohammadifar et al., 2006).

Fig. 18.1 Structure of gum tragacanth pectic component (Astragalus spp) (from Stephen and Churms, 1995).

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18.3.2 Gum karaya Chemically, gum karaya is a partially acetylated polysaccharide of the substituted rhamnogalacturonoglycan type. The exudate occurs in the salt form containing calcium and magnesium ions. It has a branched structure and a very high molecular weight (ranging from 9,000 to 16,000 kDa) (Stephen, 1990; Whistler, 1993; Stephen and Churms, 1995). It contains about 37% uronic acid residues and approximately 8% acetyl groups. Due to these acetyl groups gum karaya is insoluble and only swells in water. The native acetylated gum assumes a rather compact and branched conformation in aqueous solution. In contrast, the fully deacetylated karaya gum assumes a more expanded conformation and behaves as a random coil (Le Cerf et al., 1990). After acid hydrolysis gum karaya produces D-galacturonic acid (D-GalA), DGal, L-Rha and small proportions of D-glucuronic acid (D-GlcA). The sugar composition of gum karaya has been given as (in wt%): 37.6% uronic acids; 26.3% D-Gal and 29.2% L-Rha (Aspinall et al., 1986). However, the sugar composition of the gum is dependent on the botanical sources and age of the tree and there is also more than average variability in the proportions of amino acids in the proteinaceous components. It is worth pointing out that gum karaya has a much higher rhamnose content than other commercial exudate gums. More detailed structural studies after partial acid hydrolysis, acetolysis, methylation analysis and Smith degradation, suggest that the polysaccharide component of karaya corresponds with that shown in Fig. 18.2 (Stephen and Churms, 1995).

Fig. 18.2 Structure of gum karaya (Sterculia urens) (from Stephen and Churms, 1995).

18.3.3 Mesquite gum Mesquite gum is the neutral salt of a complex acidic branched polysaccharide formed by a core of -D-Gal residues comprising a (1!-3)-linked backbone with (1!6)-linked branches, bearing L-Ara (pyranose and furanose rings form), D-glucuronic acid and 4-O-methyl- -D-glucuronic acid (Fig. 18.3) (White, 1946, 1947a, 1947b, 1948; Cuneen and Smith, 1948a, 1948b; Akher et al., 1952; Aspinall and Whitehead, 1970a, 1970b). On acid hydrolysis mesquite gum from P. velutina yields L-Ara and D-Gal as main carbohydrate residues with Ara/Gal ratio between 7.32 and 10.61, and traces of D-Glc, D-Man and D-Xyl were also detected (LoÂpez-Franco et al., 2008). 1H NMR spectroscopy studies have recently been used to analyse the structure of gum from P. velutina (Rinaudo et

Fig. 18.3 Primary structure for the carbohydrate component of mesquite gum (from Aspinall and Whitehead, 1970a, 1970b); R Ara-(1!2)-Ara-(1!2)-Ara-(1!2)-Ara-(1!2)-Ara-(1!4)-Ara-(1!3)-Ara-(1 y Ara-(1!6)-Gal-(1!3)-Ara-(1!3)-Ara-(1.

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Fig. 18.4 Twisted hairy rope structure proposed to AGPs from gum arabic (A. senegal) (from Qi and Lamport, 1991; reproduced with permission of American Society of Plant Biologists).

al., 2008), and it was confirmed that L-Rha is not present in mesquite gum, in contrast with gum arabic whose spectrum shows the corresponding signal for this residue at ~1.32 ppm. By contrast, in the material from P. laevigata, a small concentration of L-Rha of ~1.3 mol% has been reported (Orozco-Villafuerte et al., 2003). In addition to the polysaccharide component, mesquite gum contains a small amount of protein (2±4%) (Fincher et al., 1983; Goycoolea et al., 1998; OrozcoVillafuerte et al., 2003; LoÂpez-Franco et al., 2004) which plays an important role in its emulsification properties (Vernon-Carter et al., 1996b, 1998; Goycoolea et al., 1995). The adequacy of models that explain the tertiary structure of mesquite gum has not yet been assessed experimentally. However, light scattering studies have shown that mesquite gum (P. velutina) with molecular weight of 386,000 g/mol and radius of gyration (RG) of 50.47 nm and hydrodynamic radius (RH) of 9.48 nm (LoÂpez-Franco et al., 2004), resembles a polydisperse macrocoil in agreement with the `twisted hairy rope' proposal AGP for gum arabic (Fig. 18.4) (Qi and Lamport, 1991). The intrinsic viscosity of mesquite gum has been recently given as [] 1.47 10±2 MW0.50 (mL g±1) (Rinaudo et al., 2008). From the absolute values of the constants of the Mark±Houwink relation, it follows that a very low intrinsic viscosity is obtained in consideration of the molecular weight; this is directly related to the highly branched structure. 18.3.4 Larchwood arabinogalactan Arabinogalactan from larchwood is known to be composed of two main fractions, the more abundant fraction (70±95%) being the high molecular weight

506


(MW ~ 37±100 kDa), AG-A, and a proportionally less abundant (5±30%) low molecular weight fraction (MW ~ 7.5±18 kDa), AG-B (Swenson et al., 1969; Clarke et al., 1979). It is unclear whether a typical A/B ratio exists and differences in reported ratios have been attributed to analytical methodology (Jones and Reid, 1963). The principal material available commercially is the ultrafiltered product, which is known to correspond with AG-A (Ponder and Richards, 1997a). By contrast with other plant arabinogalactans, AG-A is protein free (Clarke et al., 1979; Prescot et al., 1995). Chemically, arabinogalactans from larchwood have a general structure given by a backbone of (1!3)-linked -D-galactopyranosyl units that account for about one-third of the molecule, each of which contain a side chain at position C6. Most of these side chains are galactobiosyl units containing a (1!6)- -Dlinkage. Another side chain type that occurs is a single L-Ara unit or 3-O-( -Larabinopyranosyl)--L-arabinofuranosyl units. Less frequent is a single -DGalp or -L-Araf or a dimer -L-Arap-(1!3)--L-Araf (Ponder and Richards, 1997b). The side group distribution is not uniform and the overall ratio of Lgalactose to L-arabinose is ~6:1. Traces of uronic acid units have also been reported as part of the structure of AG-A (Ponder and Richards, 1997a). The representative chemical structure of larchwood AG is shown in Fig. 18.5. Purified AG-A has been suggested to occur naturally as ordered assemblies of molecules that can be disrupted by alkali to form individual, unassociated molecules, i.e., disordered AG (DAG) (Ponder and Richards, 1997b). This order± disorder transition can be reversed by drying or freezing. Parallel studies have shown that when AG-A (37 kDa) is treated with sodium hydroxide solutions of 0.5 M or greater and 0.1 M sodium borohydride, the average molecular weight of the resulting arabinogalactan falls approximately four-fold to yield fractions of AG (~9 kDa) (Prescot et al., 1995). Based on this evidence it has been proposed that larch AG consists of a series of subunits joined through au unknown type of linkage which is susceptible to cleavage at low alkali concentrations and moderate temperatures. 13C-NMR spectra of AG-A (37 kDa) and AG (9 kDa) are identical except that broader spectral lines are observed in the AG-A spectrum due to its greater molecular weight. Whilst in vitro comparison of both materials using isolated asialoglycoprotein receptor shows equivalent bioactivity (Prescot et al., 1995), it has been proposed that the low molecular weight material in the crude AG extract is possibly a biological precursor of the predominant, larger molecular weight form of AG in the extract (Prescot et al., 1997). More recent Xray fibre diffraction data supports a model for a curdlan-type triple helical structure for the ordered structure of arabinogalactan (Chandrasekaran and Janaswamy, 2002), whereby a galactan triple helix can accommodate disaccharide D-Gal-(1!6)-D-Gal substituents at C6 of every D-Gal unit in the main chain. This side group attachment is not unique and it can be done in several ways while preserving the helix symmetry. Under the proposed model, the arabinogalactan molecule resembles a bottle brush. AG-B is the form of AG that exists naturally as discrete molecules. It constitutes some 5% or less of a typical AG sample and its average L-Ara

Fig. 18.5 Major structural features of a typical larchwood arabinogalactan molecule (from Ponder and Richards, 1997b).

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content is about 38 mol%. It is distinguished from DAG by GPC, having a longer retention time, and its Mw is about 7,000 to 10,000 (Simson et al., 1968; Swenson et al., 1969). Neither drying nor freezing causes it to assume a multimolecular structure, and it contained no uronic acid residues.

18.4

Technical data

18.4.1 Gum tragacanth Gum powder made from ribbon is white to light yellow in colour, odourless and has an insipid, mucilaginous taste. The flakes vary from yellow to brown to give cream to tan powders in colour. Both ribbon and flake gums are available in a variety of particle sizes and viscosities depending on the end use. A typical product specification of a high grade commercial gum tragacanth powder is: Appearance: Off white to creamy coloured fine powder Loss on drying: 12% Ash: 3.0% Acid insoluble ash: 0.3% Viscosity 1% in water: 800 150 cPs Particle size: 90% through BSS 150 mesh Specifications of lower grade gum diverge from top quality gum mostly in that the colour tends to cream and yellow and viscosity values may be as low as ~280 cPs. Minimum quality and safety standards for gum tragacanth to be used in food and pharmaceutical products have been defined in the United States Pharmacopeia USP31 (USPC, 2007): Arsenic: 3 ppm Heavy metals (as Pb): 20 ppm Microbiology: Salmonella/E. coli ± absent The main inherent functional properties of tragacanth exudates are briefly discussed next. Solubility Gum tragacanth swells rapidly in either cold or hot water to form a viscous colloidal solution, which acts as a protective colloid and stabilizer. While it is insoluble in alcohol and other organic solvents, the gum can tolerate small amounts of alcohol or glycol. The gum solution is fairly stable over a wide pH range down to extremely acidic conditions at about pH 2. Viscosity The viscosity is the most important factor in evaluating tragacanth and is regarded as a measure of its quality as well as a guide to its behaviour as a

Other exudates

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suspending agent, stabilizer or emulsifier. The viscosity of 1% solutions may range from about 100±3,500 cPs depending on the grade. Ribbon types give a higher viscosity than flake types. The best quality of ribbon type gum tragacanth shows up to 3,500 cPs (1.0%, 25 ëC, 24 h, 20 rpm by Brookfield viscometer). Tragacanth highly viscous colloidal sols or semi-gels can serve as protective colloids and stabilizing agents. The high viscosity of tragacanth solutions results from the molecular characteristics of the gum, and these depend on the grade and physical form, and the manner in which it is taken up in water. For example, the same concentration of solution prepared from whole gum is more viscous than one prepared from powdered gum. Unlike many other gums, solutions of tragacanth have a very long shelf-life without loss of viscosity. The solution viscosity reaches a maximum in 24 h at 25 ëC, 8 h at 40 ëC and 2 h at 50 ëC. Fine powdered gum has shorter hydration time than coarse powder and good dispersion is needed to avoid the formation of aggregates. The maximum initial viscosity of tragacanth solutions is at pH 8, but maximum stable viscosity is at about pH ~ 5 (Stauffer, 1980). The viscosity is quite stable over a wide pH range from 2±10, particularly for the flake type of the gum (Wareing, 1997). The addition of strong mineral and organic acids causes some drop in viscosity. Divalent and trivalent cations can also cause a viscosity drop or may result in precipitation, depending on the metal ion type and concentration. Rheological properties The apparent viscosity of tragacanth solutions decreases as the shear rate increases and is reversible, with the original viscosity returning upon the reduction of the shear rate. Such pseudoplastic properties have an effect on the pouring and texture of the finished products. Acid stability Tragacanth solutions are naturally slightly acidic. A 1% solution has a pH of 5±6, depending on the grade of gum used. The viscosity is most stable at pH 4±8, but with very good stability at both the higher pH and at the lower end of pH 2. Tragacanth is one of the most acid-resistant gums, and is chosen for this characteristic for use under conditions of high acidity. However, when acids are used in the system, they should not be added until the gum has had time to fully hydrate. Surface activity Gum tragacanth has well-defined surface activity properties and produces a rapid lowering of the surface tension of water at low concentration, less than 0.25% (Glicksman, 1982a). Flake types of tragacanth (lower viscosity) are superior to the ribbon types (higher viscosity) for the reduction of surface tension and interfacial tension effects. Stauffer and Andon (1975) reported that at 1% concentration, the ribbon type gave 61.7 dynes/cm surface tension value compared with the value of 52.5 dynes/cm given by the flake type.

510


Emulsification ability Gum tragacanth, regarded as a bifunctional emulsifier, is a most efficient natural emulsifier for acidic oil-in-water emulsions. It thickens the aqueous phase and also lowers the interfacial tension between oil and water. It has a reported hydrophilic lipophilic balance (HLB) value of 11.9 (Griffin and Lynch, 1972), but it is believed HLB values run from 11±13.9 depending on the grade of the gum because flake types have lower interfacial tension between oil and water than ribbon types (Anderson and Andon, 1988). Heat stability Elevated temperatures may also affect viscosity through a thinning effect on the solution. Upon cooling, however, the solutions tend to revert to nearly their original viscosity. Prolonged heating can degrade the gum and reduce viscosity permanently. Compatibility Tragacanth is compatible with other hydrocolloids as well as carbohydrates, most proteins and fats. There is an interesting interaction, however, between gum tragacanth and gum arabic, which results in an unusual viscosity reduction that has been attributed to the molecular association between both gum species (Rabbani et al., 1995). Although the precise mechanism for this interaction is still unclear, it is exploited commercially to produce superior, thin, pourable, smooth emulsions with fish and citrus oils, which also have a long shelf-life. Preservatives Tragacanth solutions are less sensitive to microbial attacks and have longer shelf-life without loss of viscosity in comparison with other plant hydrocolloids. When preservatives are needed, glycerol or propylene glycol at 94 mL/litre serve as excellent preservatives in many emulsions. Sorbic acid, benzoic acid or sodium benzoate at less than 0.1% concentration are effective when used below pH 6. A combination 0.17% methyl and 0.03% propyl parahydroxybenzoate is effective at pH 3±9. Benzoic acid esters are also effective for maintaining solution properties throughout product preparation and shelf-life (Wareing, 1997). 18.4.2 Gum karaya Gum karaya has a slightly acetous odour and taste. The colour of the gum varies from white to tan depending on grade. Cost is based on purity and colour. Powdered karaya contains about 10±14% moisture, but the loss on drying is higher than this due to the presence of volatile substances. A typical specification for top quality commercial gum karaya is shown below (from Importers Service Corporation, NJ, USA): Appearance: Off white to buff fine powder Odour: Light acetic acid

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Taste: None Loss on drying: 20% Total ash: 5.0% Acid insoluble ash: 1.0% Particle size: 99.9% through USS 80 mesh; 98% through USS 140 mesh Viscosity 1% in water: 400 mPas Viscosity 2% in water: 8000 mPas pH 1% solution: 4.3±5.0 Salmonella: Negative E. coli: Negative Specifications for gum karaya from other manufacturers (Arthur Branwell & Co Ltd.) include maximal heavy metal contents, namely: Heavy metals (as Pb): 20 ppm Pb: 5 ppm As: 3 ppm Solubility Gum karaya is the least soluble of commercial gums and forms true solutions only at very low concentrations ( G00 moduli and no frequency dependence, thus indicating that a gel network is formed. The presence of acetyl groups in both gums seems to stabilize the gel. In turn, a separate study has shown that karaya gum forms true gels (i.e. G0 =G00 > 3) only at concentrations greater than 4% and that the addition of NaCl decreases the gel strength (Brito et al., 2005). Karaya gels studied by the latter group did not present any sharp variation in G0 or G00 with increasing temperature. pH stability The pH of a 1% solution of gum karaya is about 4.5±4.7 for Indian origin and 4.7±5.2 for African origin. The viscosity of solutions decreases upon the addition of acid or alkali. Higher viscosity can be obtained if the gum is fully hydrated prior to pH adjustment (Glicksman, 1982b). Above pH 8, alkali irreversibly transforms the characteristic short-bodied solution into a ropy, stringy mucilage as the molecules lose their acetyl groups through rapid saponification. This has been ascribed to deacetylation of the karaya molecule. Due to high uronic acid content, karaya dispersions withstand acid conditions

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quite well and resist hydrolysis in 10% hydrochloric acid solution at room temperature for at least 8 h (Whistler, 1993). Heat stability Heating karaya dispersions changes the polymer conformation and increases the solubility, but results in a permanent viscosity loss. Maximum concentrations of 4±5% can be prepared by cold water hydration, but when heating under pressure, smooth, homogeneous, translucent and colloidal solutions at concentrations as high as 18±20% can be obtained (Glicksman, 1982b). Water-binding properties Gum karaya has a strong water-binding ability. It can absorb water and swell to more than 60 times its original volume. Film-forming properties Gum karaya forms smooth films when plasticized with compounds such as glycols. Adhesive properties At high concentrations of 20±50% gum karaya in water gives heavy pastes with strong wet-adhesive properties. This enables karaya gels and pastes to resist loss of strength when diluted (Glicksman, 1982b). These are used in dental adhesives and colostomy bag sealing rings (Wareing, 1997). Compatibility Gum karaya is compatible with most gums as well as proteins and carbohydrates. Blending karaya with other gums, such as alginate, can modify the solution characteristics (Le Cerf and Muller, 1994). However, karaya gels are incompatible with pyrilamine maleate, a strong hydrotrope and antihistaminic agent. Strong electrolytes or excessive acid cause a drop in viscosity, while alkalis make karaya solutions very ropy (Meer, 1980). Preservative The viscosity of karaya solution remains constant for several days and decreases gradually with ageing, unless preservatives are used to prevent bacterial attack. Preservatives such as benzoic or sorbic acid, methyl and propyl parahydroxybenzoate, glycerol, propylene glycol, chlorinated phenols, formaldehyde, and mercuric salts, are suitable. 18.4.3 Mesquite gum Unprocessed mesquite gum is available as vitrified nodules of varying size and shape and has red amber to tan colour. Dry mesquite gum is dissolved in water to form solutions which are dextrorotatory (ca. +60ë). The Mexican Ministry of Health has proposed specifications for gum intended for use in foods (SecretarõÂa de Salud, 1996). These along with the main physico-chemical characteristics

514


Table 18.1 Analytical parameters for Prosopis velutina and specifications for P. laevigata gum

Appearance Color Loss on drying (%) Ash (total, %) Ash (acid insoluble (%)) Arsenic (as As) Heavy metal (as Pb) Lead Tannin (%) Starch or dextrin Insoluble matter (%) Specific rotation []D20 Total nitrogen (%) Protein (%)b Viscosity 20% (cps)c Microbiology pH Acid equivalent weight (g mol) Glucuronic acid (mol%) Arabinose (mol%) Galactose (mol%) Rhamnose (mol%)

P. velutina (hand sorted)

P. laevigataa

Vitrous nodules Red amber 9.7 0.1 2.6 0.01 NA NA NA NA 0.46 0.03 NA 0.6 0.1 + 66.7 5.3 0.7 0.1 4.6 0.6 25 Coliform negative 4.5 1282 3 71 26 ND

Vitrous nodules Red amber 15 4.0 0.5 3 ppm 40 ppm 10 ppm 2.0 Passes test 1.0 % + 77.0 0.4 0.07 2.6 0.06 NA NA NA NA 16.2 1.3d 40.4 2.04d 43.3 1.4d 1.3 0.2d

a

Maximum values are taken from specifications from Ministry of Health of Mexico, SecretarõÂa de Salad (1996), the rest of the values have been measured experimentally. b Protein = N 6.53. c At 20 ëC in 0.1 M NaCl. d From Orozco-Villafuerte et al. (2003). NA = Not available; ND= not detected

derived from various studies on the gums from P. velutina and P. laevigata are compiled in Table 18.1. Solubility Mesquite gum has extremely high solubility in aqueous medium, which can yield solutions above 50% (w/w) concentration (Goycoolea et al., 1995). It is also soluble in aqueous ethanol up to 70% ethanol, and has limited solubility in glycerol and ethylene glycol but is insoluble in organic solvents and oils (Vernon-Carter et al., 2000). Prosopis gum solutions present colours that vary from slight yellow or amber to a dark brown colour depending on the concentrations and botanical origin. Viscosity The viscosity of mesquite gum solutions even at high concentrations is very low when compared with that of other polysaccharide gums (Vernon-Carter and

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Sherman, 1980). At concentrations below 15% (w/v) the solutions have been reported as being `shear thickening' as the shear rate increased beyond 100 sÿ1, and attributed this effect to either a change in molecular shape at high shear rates or to an experimental artifact caused by turbulent flow in the coaxial cylinder geometry used. The viscosity of 20% (w/w) solutions in 0.1 M NaCl at 25 ëC was ~25±30 mPas and presented a Newtonian behaviour (Goycoolea et al., 1995), though shear thinning occurred at greater concentrations. At concentrations of 50% (w/v) mesquite gum solutions exhibited a clear nonNewtonian behaviour (Rinaudo et al., 2008). Effect of pH The functional properties of mesquite gum are affected by pH. The relative viscosity ( rel) of mesquite gum solutions increases as pH increases from 4.0 to 7.0, due to the substitution of the H+ ions by Na+ ions with a greater degree of dissociation, leading to the macroion unfolding and hence to the increase in viscosity. As the pH increases from 7.0 to 9.0 the macroion cannot expand further due to steric constraints, and as the amount of Na+ counterions increases, they shield the macroion charges and cause it to fold and hence the solution viscosity to decrease (Vernon-Carter et al., 2000). In turn, it has been observed that the effective electrical surface charge (given by the zeta potential) of orange oil-in-water emulsions stabilized with mesquite gum, increases with pH reaching an approximately constant value at pH ~7.0. As the concentration of added NaCl increases from 10ÿ3 to 10ÿ2 M, the compression of the electrical double layer, due to charge shielding, leads to a comparatively lower zeta potential values at all pHs (Acedo-Carrillo et al., 2006). Surface activity Mesquite gum solutions reduce the interfacial tension as a function of the concentration and time (Vernon-Carter and Sherman, 1981). As the gum concentration increases in the range 0.5±25%, the interfacial tension decreases faster. The solution pH also influences the lowering of the interfacial tension with time, an effect that has been directly related to the mesquite gum conformation in solution. The more compact mesquite gum molecular species are, the faster and lower is the decrease in interfacial tension. This has been attributed to the diffusion and/or the conformation of the gum species at the interface. In parallel studies, the absorption of water and oil by mesquite gum at temperatures in the range of 23±45 ëC were greater than those of gum arabic. The activation energy values obtained for water and oil absorption for gum arabic were 21.98 and 39.57 kJ molÿ1, respectively, compared to those of mesquite gum with values of 15.79 and 46.16 kJ molÿ1, respectively (Beristain et al., 1996). In separate studies, changes in the surface tension of an orange oil±water interface, as probed by a Wilhemly plate, were measured. These measurements showed that the adsorbed surface per molecule for gum arabic was an order of magnitude greater than that of gum mesquite (23.0 and 2.2 nm2, respectively)

516


(Goycoolea et al., 2000), revealing that the structural microheterogeneity plays a key role in the functional behavior of these materials. In turn, mesquite gum and its major fractions, separated by hydrophobic affinity chromatography, of varying protein contents (7.18±38.60%) and macromolecular dimensions (Mw ~ 3.89 105±8.06 105 g mol-1, Rg ~ 48.83±71.11 nm, Rh ~ 9.61±24.06 nm), have been studied in Langmuir monolayers spread at an air±water interface and compared with whole gum arabic and its corresponding fractions (LoÂpez-Franco et al., 2004). The most active species at the interface were those containing greater amounts of protein. These results have been related with the fine structural differences between the constituent macromolecular species comprising the gum (LoÂpez-Franco et al., 2004). Emulsification ability Like gum arabic, mesquite gum also forms and stabilizes oil-in-water emulsions and has the ability to encapsulate orange citrus oil during spray drying (Goycoolea et al., 1997; Vernon-Carter et al., 1996b; Beristain et al., 1996). Mesquite gum solutions of 15 w/w% are able to form emulsions with n-decane, n-dodecane, n-tetradecane and n-hexadecane with mean droplet diameters of 4± 4.5 m; whereas with orange oil the average droplet diameter was found to vary in the range 2.5±3.0 m (Valdez et al., 2006; Acedo-Carrillo et al., 2006). Moreover, the particle size of emulsions of orange oil-in-water stabilized with 1% mesquite gum remained unchanged for up to 100 h. By contrast, in emulsions with D-limonene and n-decane, phase separation starts within the first 24 h (Acedo-Carrillo et al., 2006). This behaviour of mesquite gum on the orange oil emulsions to stop or control Ostwald ripening is attributed, among other causes, to the fact that orange oil is less water soluble than D-limonene. In addition, mesquite gum-stabilized emulsions of orange oil showed the ability to form a gel structure with time, in contrast with similar emulsions stabilized with gum arabic, with those obtained with alkane oils and with D-limonene. These results seem to indicate that the nature of the oil used is a key factor for gel formation and for the prolonged stability of the emulsions formed with mesquite gum (Valdez et al., 2006; Acedo-Carrillo et al., 2006; Rinaudo et al., 2008). In other studies, it has been found that mesquite gum with a nitrogen content of 0.49% had better emulsifying capacity for chilli oleoresin than gum arabic with nitrogen contents of 0.35% (Vernon-Carter et al., 1996b). The mesquite gum stabilized emulsions had similar initial particle size and exhibited monodisperse particle size distribuition over 8 days, while gum arabic emulsions had a larger initial particle size and polydisperse particle size distribution that broadened with ageing time up to 8 days. Encapsulation ability Several materials are commercially available for encapsulation of essential oils, flavours, colorants and vitamins by spray-drying. The most widely used encapsulation agents are gum arabic and modified or hydrolysed starches. Mesquite gum has been reported as having the ability to encapsulate orange peel oil

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(Goycoolea et al., 1997) (80.5% of the starting oil) (Beristain and VernonCarter, 1994). A blend of 60:40% gum arabic to mesquite gum was able to encapsulate the same amount of orange peel oil as pure gum arabic (Beristain and Vernon-Carter, 1995), whereas a 3:2 ratio of maltodextrin 10 DE to mesquite gum, retained 84.6% of the starting orange peel oil, thus providing a better encapsulating capacity. Film forming Mesquite gum-based films have become an important research topic mainly due to their ability to regulate moisture, lipid and gas migration. Such films can be used to extend the shelf-life of foodstuffs. Emulsion films using mesquite gum as structural agent and a blend of candelilla wax with white mineral oil as the lipid phase, prolong the shelf-life of treated guava fruit (Psidium guajava L.) by retarding ethylene emission and enhancing the texture of the fruits (TomaÂs et al., 2005a). On the other hand, blends of mesquite gum (Prosopis spp) with whey protein concentrate, have been reported to form edible films with poor moisture barrier properties (TomaÂs et al., 2005b). A complex of mesquite gum and chitosan complex has also been used to form edible films again with low water vapour permeability (RuõÂz-Ramos et al., 2006). Compatibility Mesquite gum has been used successfully for various purposes in combination with other gums (e.g., gum arabic), maltodextrins, lipids (candelilla wax), vegetal and animal proteins (e.g., corn zein, soy, whey, peanut proteins, gelatin, casein and milk whey proteins) and with other polysaccharides such as chitosan (RuõÂzRamos et al., 2006; PeÂrez-Orozco et al., 2004), sodium alginate and carrageenan (TomaÂs et al., 2004). Blends of gum arabic and mesquite gum exhibited a synergistic effect that provided greater long-term stability against drop coalescence than either component on its own; however, mesquite gum provided better stability against drop coalescence and deterred pigment degradation better than gum arabic and its blends (Vernon-Carter et al., 1996b). When mixed with gelatin, mesquite gum forms complex coacervates at a 1:1 mass ratio. Microcapsules based on this complex coacervate system have been exploited in encapsulation of corn and orange oil (Vernon-Carter et al., 2000). Preservatives Mesquite gum solutions can be preserved with benzoic acid, formic acid and phydroxybenzoic acid or a combination of sodium benzoate, potassium sorbate and citric acid (Vernon-Carter et al., 2000). 18.4.4 Larchwood arabinogalactan Commercial larch arabinogalactan (LAG) is a dry slightly yellow free-flowing powder with a very slight pine-like odour and sweetish taste (Kelly, 1999). Food grade LAG (98% purity) is free of phenolic, terpenoid or other extraneous chemical and is completely colourless, odourless and tasteless. This material is

518


used for clinical applications. Low purity arabinogalactan has significant levels of polyphenolic lignin impurities which impart a light yellow colour and strong odour. Typical specifications for food grade LAG are given below (from Lonza Ltd): Appearance: Fine, off-white to white free-flowing powder Carbohydrates > 90% Physical state: Texture ± free-flowing powder; flavor ± minimal; odor ± minimal Color (CWF): L > 85; a ± Record; b 60 Dissolution: Sink ± wet pass; lumps ± None Heavy metals < 5 ppm Lead 1), whereas

668


those of aleurone (Ara/Xyl < 0.5), and especially hyaline layer are poorly substituted (Ara/Xyl < 0.3) (Antoine et al., 2003; Barron et al., 2007; Saulnier et al., 2007). The ratio of Ara/Xyl in wheat endosperm generally varies from 0.50 to 0.71. Similar differences in the degree of substitution of arabinoxylans due to their histological origin have also been demonstrated in barley (Izydorczyk and Dexter, 2008). The ratios of Ara/Xyl in arabinoxylans from pericarp tissues were almost twice as high as in arabinoxylans from aleurone of both hulled and hullless barley cultivars; whereas arabinoxylans from the endosperm CW exhibited intermediate values (Table 23.2). The extent of feruloylation of arabinoxylans in barley and wheat is also tissue dependent (Table 23.2). Arabinoxylans in the CW of starchy endosperm are very lightly esterified with ferulic acid, whereas the arabinoxylans of aleurone and pericarp tissues are highly esterified. p-Coumaric acid, although in lower abundance than ferulic acid, is associated with arabinoxylans from pericarp. Notably, the arabinoxylans in the CW of starchy endosperm and aleurone have low amounts of esterified dehydrodiferulic acid (DDFA), whereas those in pericarp are extensively crosslinked by DDFA (Table 23.2). The cellular variations are masked when arabinoxylans are extracted from whole grains. Storsley et al. (2003) reported the ratio of Ara/Xyl in the range of 0.59±0.77 for water-extractable and in the range of 0.51±0.64 for waterunextractable arabinoxylans from the whole grain of eight Canadian hull-less barley genotypes. Similar values of Ara/Xyl (0.64±0.78) were reported by Oscarsson et al. (1996) for arabinoxylans from six Swedish genotypes of hullless barley. In rye whole grain, the ratio of Ara/Xyl may vary from 0.50±0.82 (Vinkx and Delcour, 1996). The Ara/Xyl ratios of wheat arabinoxylans were also cultivar dependent, as shown by the range of Ara/Xyl in water-extractable (0.47±0.58) and water-unextractable arabinoxylans (0.51±0.67) obtained from 20 French wheat flours (Ordaz-Ortiz and Saulnier, 2005). The fine molecular structure of arabinoxylans is better described by the substitution pattern of the xylan backbone with Araf residues. All four structural elements, unsubstituted, monosubstituted (at O-2 or O-3), and disubstituted (O2,3) Xylp residues have been identified in cereal arabinoxylans, but their relative amount vary with genotypic and cellular origin of these polysaccharides. For example, in wheat, the monosubstituted Xylp units at O-2 are rare (0.3±1.9%) (Cleemput et al., 1995; Saulnier et al., 2007) whereas in barley such substituted Xylp residues are relatively abundant (Oscarsson et al., 1996; Izydorczyk et al., 2003b). The content of O-2 monosubstituted Xylp ranged from 6% to 16% in water-extractable arabinoxylans from whole meal of hull-less and hulled Swedish genotypes (Oscarsson et al., 1996), and from 6% to 14% in Ba(OH)2extractable arabinoxylans from Canadian hull-less genotypes (Storsley et al., 2003). The water-soluble arabinoxylans from barley grain generally contain 47±65% of unsubstituted, 20±25% monosubstituted and 19±26% disubstituted xylose residues (Oscarsson et al., 1996; Izydorczyk et al., 1998a, 1998b; Dervilly et al., 2002; Storsley et al., 2003; Trogh et al., 2004). Some genotypic differences in

Arabinoxylans

669

the patterns of substitution were observed when the alkali-extractable arabinoxylans from eight Canadian hull-less barleys were investigated; it was noted, for example, that the amount of unsubstituted Xylp was higher in high amylose and normal genotypes than in waxy lines, but some variations were also observed between lines within the same type of barley (Storsley et al., 2003). The differences in substitution patterns in water-extractable arabinoxylans from pearling by products and fiber-rich fractions were more pronounced; in general, the water-extractable arabinoxylans from PBPs were more substituted, contained a lower amount of unsubstituted Xylp, and higher amount of monosubstituted Xylp at O-2 than their counterparts in the fiber-rich fraction. It is generally agreed that cereal arabinoxylans are highly polydisperse and consist of range of structures with different degree and pattern of distribution. However, the distribution of Araf along the xylan backbone is non-random in all cereal arabinoxylans. The tentative structural models for arabinoxylans suggest that highly substituted regions, abundant in disubstituted Xylp and sequences of contiguously substituted Xylp, are separated by less densely substituted regions, with blocks of contiguously unsubstituted Xylp and Xylp residues more frequently mono- than disubstituted (Vietor et al., 1992; Gruppen et al., 1993; Izydorczyk and Biliaderis, 1995; Vinkx et al., 1995). For the water extractable arabinoxylans from wheat endosperm, it was shown that the less substituted fractions of wheat arabinoxylans, obtainable by precipitation at a relatively low concentration of ammonium sulphate or ethanol, may contain sequences of at least up to six but possibly more contiguously unsubstituted xylose residues. In the highly substituted regions (or entire chains), on the other hand, blocks of up to six contiguously substituted xylosyl residues were found (Dervilly-Pinel et al., 2004). It appears that during biosynthesis of arabinoxylans, the arabinosyl tranferases favour di-substitution and contiguous substitution of xylosyl residues and that arabinoxylans initially deposited in CW are heavily substituted with Araf residues (Gibeaut et al., 2005). The de-arabinosylation, probably mediated by the action of arabifuranohydrolases, is occurring in response to external stresses during the plant development, such as changes in temperature, availability of metabolites or the presence of pathogens. The removal of Araf from the initially heavily substituted arabinoxylans is in agreement with the nonrandom pattern of Araf substitution along the xylan backbone (Dervilly-Pinel et al., 2004).

23.5

Analysis and detection

The content of arabinoxylan in grain and grain fractions can be determined by the colorimetric phloroglucinol-HCl or orcinol-HCl reactions which show high but not absolute specificity for pentoses (Douglas, 1981). Alternatively, the arabinoxylans content can be derived from the amount of Ara and Xyl residues following complete hydrolysis of grain/tissues or preparations containing these polymers, followed by chromatographic analyses (HPLC or GC) (Izydorczyk

670


and Biliaderis, 1995). The water soluble arabinoxylans can be quantified after extraction with water and determination of pentose sugars by colorimetric or chromatographic methods. Viscosity measurements of the water extracts from ground grain provide an indirect way of estimating the content of water-soluble arabinoxylans; this method, however, is affected by the presence of endogenous or microbial endoxylanases that would affect the results (Saulnier et al., 1995b). NIR spectroscopy can also measure arabinoxylans content (Hong et al., 1989; KacuraÂkovaÂ et al., 1994). 1 H-NMR and 13C-NMR spectroscopy and methylation analysis are considered reference methods to elucidate the fine molecular features of arabinoxylan's structure such as linkage composition and the presence and amount of sugar residues and various substitutions (Izydorczyk and Biliaderis, 1995). These methods, however, require relatively large amount of isolated and purified material and are tedious to use on a large number of samples. Ferulic acid monomers and dimers may be analyzed directly by HPLC after saponification (Waldron et al., 1996) or by GC as their trimethylsilyl derivatives (Lam et al., 1990). Partial hydrolysis of arabinoxylans with endoxylanases and subsequent chromatographic analysis of the hydrolysis products, constitute an alternative method to study the molecular structure of these polymers. Arabinoxylooligomers and xylooligomers can be separated and quantified by high performance anion exchange chromatography, whereas the structure elucidation of the oligomers can be conducted by 1H-NMR spectroscopy or matrix-assisted laser desorption/ionization time-of-flight/time-of-flight (MALDI-TOF/TOF) tandem mass spectrometry (Maslen et al., 2007). The xylanase action is influenced by the structure of arabinoxylans, and the type and amount of specific degradation products give information about their molecular features. Xylanase hydrolysis can be carried out on various grain tissues, flour, and whole grain (Ordaz-Ortiz et al., 2004). Fourier transform infrared (FT-IR) and FT-Raman spectroscopy can be applied in complementary ways to determine structural features of arabinoxylans (KacuraÂkovaÂ et al., 1999; Philippe et al., 2006a). Both FT-IR and Raman microspectroscopy have been shown to be useful in investigation of in-situ cell wall composition. FT-IR microspectroscopy with principal component analysis discriminates between AX with different degrees of arabinosylation in walls of starchy endosperm and aleurone (Barron et al., 2005; Robert et al., 2005; Toole et al., 2007). Raman spectroscopy (Piot et al., 2001; Barron et al., 2006; Philippe et al., 2006b) also allows determination of structural heterogeneity and relative concentrations of arabinoxylans and additionally of ferulic acid content and protein ratios in walls of grain sections. Philippe et al. (2006a) used confocal Raman microspectroscopy to determine spatial and temporal changes in the structure of arabinoxylans during grain development. A number of polyclonal and monoclonal antibodies, raised against AX with both high and low degrees of substitution, allows their location and

Arabinoxylans

671

differentiation in cereal tissues with light and electron microscopy (Migne et al., 1999; Ordaz-Ortiz et al., 2004; McCartney et al., 2005). Using gold-labeled monoclonal antibodies to arabinoxylans and -glucans and autofluorescence, Philippe et al. (2007) tracked the changes in the composition of cell walls and the deposition of ferulates in the developing wheat grains.

23.6

Physico-chemical properties

23.6.1 Molecular weight The reported molecular weight values for arabinoxylans have shown considerable variations influenced by extraction procedures, purity of preparations, and methods of determination (Izydorczyk and Biliaderis, 1995). Specific chain conformation, polydispersity with regard to molecular mass, and possible molecular aggregation pose some difficulties associated with accurate determination of the molecular weight of arabinoxylans by size exclusion chromatography using dextran or pullulan standards for calibration. More recently, the use of light scattering detectors and application of suitable techniques (e.g., alkali solvents, sonication) to aid solubilization and prevent chain aggregation alleviated some of the problems. The weight average molecular weight (Mw) of water extractable arabinoxylans of wheat of approximately 300,000 Da was determined by Dervilly et al. (2001) using HPSEC with light scattering detector. As shown in Fig. 23.8, a range of Mw varying from 220,000 to 700,000 Da was determined for arabinoxylans fractions obtained by sequential fractionation of polymers isolated from wheat flour with water. Dervilly et al. (2001) also reported several populations with Mw varying from 70,000 to 655,000 Da and Ara/Xyl ratio from 0.4 to 1.2 obtained from water extractable wheat arabinoxylans with Mw of 280,000 Da and polydispersity index (Mw/Mn) of 1.8. The water-insoluble arabinoxylans require extraction

Fig. 23.8 High performance size exclusion chromatographs (HPSEC) of two arabinoxylan preparations from wheat flour. The average Mw were determined by HPSEC-multiangle light scattering detector (unpublished results).

672


procedures that may cause degradation of the polymeric chains. Nevertheless, higher values (850,000 Da) were reported for alkali extractable wheat endosperm arabinoxylans than for their water soluble counterparts (Gruppen et al., 1992). Also high Mw values were reported for Ba(OH)2-extractable arabinoxylans from hull-less barley (850,000±2,430,000 Da) (Izydorczyk et al., 2003b). Lowly substituted arabinoxylans (corn bran, rye bran) have a strong tendency to aggregate that precludes them from proper characterization in aqueous systems without chemical derivatization (e.g., xylan sulphates or carbanilates) (Ebringerova and Heinze, 2000). 23.6.2 Solution properties The solubility of arabinoxylans in aqueous solutions is closely related to the presence of the arabinose substituents along the xylan backbone. Andrewartha and co-workers (1979) demonstrated that with removal of Araf side units the solubility of arabinoxylans can drastically decline, especially below the Ara/Xyl ratio of 0.43. It is postulated that the debranched chains aggregate, and eventually precipitate out of solution, by forming non-covalent associations between unsubstituted regions of the polymer chains. The solubility of arabinoxylans is also affected by the pattern of distribution of Araf along the xylan backbone as well as by the chain length. Izydorczyk and MacGregor (2000) provided empirical evidence of non-covalent interactions between sparsely substituted arabinoxylan chains (Ara/Xyl 0.18±0.32) and cellulose-like fragments of -glucans. The initial solubility/extractability of arabinoxylans from the CW networks is directly related to the extent of non-covalent selfassociation and intermolecular interactions with other CW constituents as well as to covalent crosslinking of arabinoxylans (through ferulic acid residues) among themselves or to lignins and proteins. Recent studies, based on light scattering measurements, indicate that arabinoxylan molecules may have extended lengths, and in solution behave as locally stiff, semi-flexible random coils whose flexibility is largely unaffected by the Ara/Xyl ratio in the range of 0.39±0.82 (Dervilly-Pinel et al., 2001; Picout and Ross-Murphy, 2002). The conformational parameters such as the exponent à' of 0.74, derived from the Mark±Houwink equation ( KMwa ) and the hydrodymanic parameter `v' of 0.47, calculated from the radius of gyration and molecular weight relationship (Rg Mwv ), determined for watersoluble fractions of wheat arabinoxylans, indicated a random coil conformation for these polymers. However, the persistent length (Lp) parameter, which is a direct measure of polymer chain rigidity, was reported to be 7:8 1:4 nm (Dervilly-Pinel et al., 2001) or 3:1 0:3 (Picout and Ross-Murphy, 2002), and indicated that arabinoxylans chains are semi-flexible in comparison with very flexible polymers such as pullulans (Lp 1:7 nm) or very stiff polymers represented by xanthan gum (Lp 100±150 nm). Due to the high Mw and locally stiff semi-flexible coil conformation, arabinoxylan chains occupy large hydrodynamic volumes (Izydorczyk and Biladeris,

Arabinoxylans

673

Fig. 23.9 Effect of shear rate on the apparent viscosity of aqueous solutions of arabinoxylan fractions with variable intrinsic viscosity values (indicated in brackets). Adapted from Izydorczyk and Biladeris (1992a).

1992b; Vinkx and Delcour, 1996), and, therefore, display viscosity building properties in solutions. The viscosity of arabinoxylan solutions is dependent on polymer concentrations and Mw (Figs 23.9 and 23.10). In dilute solutions, the zero shear rate specific viscosity (sp)0 increases linearly (with a slope ~ 1) with increasing c, where c is the concentration and the intrinsic viscosity (Table 23.3). Above the critical polymer concentration, marking the onset of coil overlap, the viscosity dependence on polymer concentration is much greater (slope ~3.7±3.9 for wheat arabinoxylans) (Table 23.3) (Izydorczyk and Biliaderis, 1992b). The apparent viscosity of concentrated arabinoxylan solutions is also strongly dependent on the rate of shear; at low shear rates arabinoxylan solutions behave like Newtonian fluids, whereas at high shear rates they exhibit shear thinning characteristic for pseudoplastic materials (Figs 23.9 and 23.10). Izydorczyk and Biliaderis (1992b) showed that wheat arabinoxylans with relatively high molecular weights may form weak pseudo-gels as evidenced by changes of the viscoelastic properties of arabinoxylan fractions from that of viscous solution (G} > G0 at all frequencies) to weakly elastic (G0 > G} at higher frequencies) (Fig. 23.10). Warrand et al. (2005) emphasized the importance of hydrogen bonds in stabilizing arabinoxylan macrostructures in aqueous solutions. These weak gel properties of arabinoxylans can be diminished in the presence of chaotropic salts, known for weakening the hydrogen bonds between solute molecules. The viscosity building properties are probably the most important characteristics responsible for many technological properties of arabinoxylans in food systems and functions in the digestive tract of humans (Lu et al., 2000; Zunft et al., 2004).

Fig. 23.10 Effect of shear rate and polymer concentration on the apparent viscosity of arabinoxylan solutions (left); and frequency dependence of elastic (G0 ) and viscous (G00 ) moduli at various polymer concentration. Adapted from Izydorczyk and Biladeris (1992a).

Arabinoxylans

675

Table 23.3 Molecular and physico-chemical characteristics of arabinoxylan fractions obtained by stepwise precipitation with ammonium sulphate and gel filtration chromatography Arabinoxylan Ara/Xyl fraction

(dl/g)

c* (g/100 ml)

Slope

F60a F70 F80 F95

0.58 0.71 0.85 0.88

4.70 4.20 3.16 1.90

0.26 0.31 0.38 nd

1.13 1.12 1.07 nd

2.19 2.04 2.00 nd

35.0 0.33 0.05 0.02

F1b F2 F3 F4 F5

0.69 0.68 0.66 0.65 0.63

8.5 6.2 4.3 3.8 3.4

0.17 0.20 0.28 0.29 0.30

1.1 1.1 1.1 1.1 1.1

3.9 3.7 3.8 3.8 3.9

61.4 48.0 15.5 6.8 4.9

Dilute region

Elastic modulusc, G0 Concentrated (Pa) region

a

Fractions obtained by stepwise precipitation of isolated and purified water-soluble wheat flour arabinoxylans with ammonium sulphate; the numbers 60±95 indicate the saturation level of ammonium sulphate. b Isolated and purified water-soluble wheat flour arabinoxylans were fractionated by size exclusion chromatography. c Solutions of arabinoxylan fractions were treated with horseradish peroxidase (0.22 PU/ml) and H2O2 (1.5 ppm); the reported values are for gels/viscous solutions at polymer concentration of 1.0% w/w. Adapted from Izydorczyk and Biliaderis (1992a,b).

23.6.3 Gelation Cereal arabinoxylans containing ferulic acid residues are capable of forming gel networks stabilized by covalent crosslinks between feruloyl groups of neighboring chains. Gelation of arabinoxylans is induced by free radical generating agents such as H2O2/peroxidase, laccase/oxygen, linoleic acid/ lipoxygenase, ferric chloride. Several dehydrodiferulates 8-50 , 8-O-40 , 8-80 , and 5-50 in the proportion 5:3:1:1 are formed by H2O2/peroxidase catalyzed oxidative coupling indicating that both the aromatic ring and the propenoic chain are involved in dimerization. As gelation of arabinoxylans proceeds, the peaks at max 320 and 375 nm in the UV spectra due to ferulic acid residue diminish, since the newly formed dehydrodiferulates have lower absorption (Izydorczyk et al., 1990). The gelation progress can also be followed by small oscillatory measurements. Usually, a rapid rise of the elastic modulus (G0 ) upon addition of the free radical agent is followed by slower increases; this behavior is attributed to formation of crosslinks between neighboring chains followed by limited restructuring due to impediment of chain movements associated with dramatic increases of viscosity (Fig. 23.11(a)). The kinetics of gelation depend on temperature, pH, and the type and concentration of the oxidizing agent.

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Fig. 23.11 (a) Development of elastic modulus (G0 ) during gelation of arabinoxylans. Insets show the mechanical spectra of arabinoxylans before and after gelation. (b) Concentration and molecular size dependence of elastic modulus (G0 ) for arabinoxylan fractions with various intrinsic viscosities after 1 h of treatment with horseradish peroxidase (0.22 PU/ml/H2O2 (1.5 ppm) at 15 ëC. Adapted from Izydorczyk and Biladeris (1992a,b).

Molecular features of arabinoxylans affect the gelling potential and rigidity of gels. Generally, strong gel networks are obtained with arabinoxylans having high content of ferulic acid residues, high molecular weight (Fig. 23.11(b)) and a low degree of substitution (Table 23.3) (Rattan et al., 1994; Izydorczyk and Biliaderis, 1995; Dervilly-Pinel et al., 2001; Carvajal-Millan et al., 2005). The concentration of polymers and oxidizing agents also affect the rate and extent of gelation. Simultaneous formation of non-covalent bonds (H-bonding) between arabinoxylans chains (governed by their molecular features) contributes to the overall strength of arabinoxylans gels (Carvajal-Millan et al., 2005).

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23.7 Technological functionality and potential applications of arabinoxylans 23.7.1 Role of arabinoxylans in bread-making Arabinoxylans play a significant role in various stages of the bread-making process as well as affecting the storage, organoleptic, and nutritional properties of the final product. Clear distinction, however, has to be made between watersoluble arabinoxylans and the population of water-unextractable polymers. The influence of arabinoxylans is already evident during the first steps of dough preparation, involving water addition and ingredient mixing. According to Bushuk (1966), arabinoxylans in wheat flour have disproportionally high water absorption properties (22%) in relation to their absolute content. When added to wheat flour, both water-soluble and water-unextractable arabinoxylans absorb large amounts of water, thus depleting the pool available for proper gluten development and film formation. Biliaderis et al. (1995) used two preparations of arabinoxylans to demonstrate the effect of molecular size of these polymers on baking absorption and showed that the high molecular weight arabinoxylans increased the farinograph water absorption to a greater extent than their low molecular weight counterparts. The addition of water soluble AX to dough negatively affects gluten yield and results in an increased resistance of dough to extension and a decrease in dough extensibility (Michniewicz et al., 1991; Wang et al., 2004). These effects, however, can be corrected by adding more water or adding xylanase containing enzyme preparations which release arabinoxylanbound water. The involvement of arabinoxylans in moderating dough behavior and improving loaf volume was clearly demonstrated by the action of endogenous and added xylanases (McCleary, 1986; Rouau et al., 1994; Petit-Benvegnen et al., 1998). Water-soluble arabinoxylans are believed to increase the viscosity of the dough aqueous phase and, therefore, to have a positive effect on the dough structure and its stability, especially during the early baking processes when a relatively high pressure is generated inside the gas cells. The increased stability of the film surrounding the gas cells is useful in prolonging the oven rise and preventing coalescence. Santos and co-workers (2005) reported that the presence of water-soluble pentosans reinforced the gluten network and decreased the irreversible changes occurring during heating the gluten. As a consequence, loaf volume and crumb structure are enhanced by the addition of water soluble arabinoxylans to doughs (Fig. 23.12) (Delcour et al., 1991; Michniewicz et al., 1991; Biliaderis et al., 1995). The overall effect of arabinoxylans on the breadmaking process is, however, dependent on the concentration and molecular structure (size) of these polymers in the dough system. Higher than optimum amount of arabinoxylans may cause viscosity buildup and hinder their beneficial effects. Water-insoluble arabinoxylans that remain in a dough system as discrete particles (i.e., cell wall fragments) can form physical barriers for the gluten network during dough development. The resulting gluten has lower extensibility

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Fig. 23.12 Effect of concentration of high and low molecular weight arabinoxylan preparations on specific volume of bread baked from good (a) and poor (b) quality wheat flours. Reproduced with permission from Biliaderis et al. (1995).

and a lower rate of aggregation (Wang et al., 2003). During fermentation, water insoluble arabinoxylans decrease the film stability. Water-unextractable arabinoxylans depress loaf volume and create coarser and firmer crumbs. However, their negative effects can be reversed by using endoxylanases with specificity towards the water-insoluble arabinoxylans (Courtin and Delcour, 2002). These enzymes catalyze the conversion of detrimental water-insoluble arabinoxylans to the high molecular weight water-soluble counterparts. The addition of optimal doses of xylanases has been reported to improve dough consistency, fermentation stability, oven rise, loaf volume, and crumb structure

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and softness (Hilhorst et al., 1999; Courtin and Delcour, 2002; Jiang et al., 2005). Biliaderis et al. (1995) demonstrated that over a 7-day storage period, the arabinoxylan-fortified breads exhibited lower crumb firmness than the controls. The effects were attributed to the increased moisture content of breads substituted with arabinoxylans and to the plasticizing effects of the additional water on the starch±gluten matrix. Contrary to the observed decrease in crumb firmness, bread supplemented with arabinoxylans showed higher starch retrogradation rates, as measured by differential scanning calorimetry and xray diffraction. The enhanced kinetic of chain re-ordering in amylopectin was attributed to greater mobility of the starch molecules in the presence of additional water. As previously established (Zeleznak and Hoseney, 1986) starch retrogradation increases with increasing moisture content, especially between 20 and 45% moisture in the system. Gudmudson et al. (1991) showed that the rate of amylopectin crystallization in starch gels containing arabinoxylans is either increased or decreased, depending on the final water content of starch; retrogradation was minimal in starch gels with moisture content below 20% and increased significantly in gels with moisture content between 20 and 30%. Breadcrumb supplemented with arabinoxylans had a coarse alveolar structure compared with control breads and breads baked with added soluble protein; the results were interpreted in terms of the different effects of added polysaccharides and protein on the properties of the liquid film over the alveoli (Fessas and Schiraldi, 1998). 23.7.2 Applications of arabinoxylans Aqueous extraction of arabinoxylans from grain and agricultural by-products provide potentially suitable material for use of arabinoxylans as gelling agents, cryostabilizers, as a source of prebiotics, and various non-food applications such as film formation and cosmetics. Arabinoxylans gels exhibit tremendous water-holding capacity of up to 100 g of water per gram of dry crosslinked polymer. The hydration properties of crosslinked arabinoxylans are not sensitive to electrolytes contrary to many synthetic hydrogels. The capacity of arabinoxylans to imbibe water increases with increasing number of effective crosslinks up to the optimum concentration, beyond which water penetration into the network and swelling are impeded due to a high density of crosslinks. Vansteenkiste et al. (2004) showed that proteins embedded in the arabinoxylan gel network resist enzymic hydrolysis. Since the rheological properties of arabinoxylan gels can be controlled by either altering the initial ferulic acid content or the concentration of polymers before gelation, their capacity to load and release proteins can also be manipulated (CarvajalMillan et al., (2005). The possibility to modulate protein release from arabinoxylan gels makes them useful for controlled delivery of therapeutic proteins and potentially for controlled releases of active agents in the food, cosmetic and pharmaceutical industries.

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Film formation Carbohydrate films and coatings can effectively control moisture, oxygen, lipid, aroma, and flavor of food systems, thus improving quality, safety, and shelf-life of products. Arabinoxylans from various grains and by-products have been shown to form films of high strength and lubricity with and without addition of plasticizers. Arabinoxylans from maize bran have been cast into edible films which are soluble, form a continuous and cohesive matrix, with neutral taste and odor, and have mechanical barrier properties similar to films of gluten or starch (Chanliaud, 1995). Arabinoxylans from barley husk have been shown to form films without addition of plasticizers (Sternemalm et al., 2008). The material properties and performance of arabinoxylan films can be further enhanced. Hydrophobic films have been produced by covalent binding of lauryamine chains to maize bran arabinoxylans (Fredon et al., 2002). Composite hydrogenated palm oil-arabinoxylan emulsion films were shown to have improved water barrier efficiency and surface hydrophobicity, but lower tensile strength and elasticity (PeÂroval et al., 2002). Edible arabinoxylans films with decreased water vapor permeability have been created by grafting !-3 fatty acids onto arabinoxylans chains using cold oxygen plasma and electron beam irradiation; the targeted application of these films was in dry biscuit coatings to delay moisture absorption from stuffing (PeÂroval et al., 2003). Partial removal of arabinose residues from the xylan backbone of rye arabinoxylans resulted in formation of semicrystalline films with lower oxygen permeability (HoÈije et al., 2008). The moderately debranched films with the Ara/Xyl ratio of 0.37 exhibited yielding and had stress/strain behavior similar to synthetic semicrystalline polymers, which in combination with oxygen barrier properties make it attractive for packaging material. Cryostabilizers Water-soluble arabinoxylans are potential candidates as cryostabilizing agents in food and drug preparation. Their ability to inhibit ice formation can be explained by enhancement of bulk viscosity and mechanical interference with growth of ice crystals on cooling. The state diagrams of wheat arabinoxylans-H2O binary mixtures have been determined (Fessas and Schiraldi, 2001) using two preparations with Ara/Xyl ratios of 0.66 and 0.51, molecular weight 235,000 and 650,000 Da and dispersity values of 4.2 and 1.6, respectively. The glass transition temperature, Tg0 , the lowest temperature at which liquid is still present, was higher for the higher Mw polymers (ÿ17 ëC) than for the low Mw (ÿ35 ëC) and the Xg0 , which is related to the solute composition at Tg0 , was one order of magnitude lower for the low Mw than the high Mw arabinoxylans. Surface active agents Some arabinoxylans exhibit surface active properties that make them suitable for stabilizing emulsions and protein foam. The small amounts of phenolic compounds and proteins may give arabinoxylans some capabilities for hydrophobic interactions. The abilities of arabinoxylans to retain gas in dough

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and protect protein foam against thermal disruption were attributed to their viscosity and film-forming properties (Hoseney, 1984; Izydorczyk et al., 1991).

23.8

Physiological effects of arabinoxylans

Since humans do not produce any autochthonous enzymes that degrade the cell wall polysaccharides, arabinoxylans contribute very little to the digestible energy. Depending on the source and methods of preparations (isolates vs. grain fractions vs. hydrolyzates), arabinoxylans pose properties of soluble and/or insoluble fiber. Due to their thickening properties, water-soluble arabinoxylans are thought to enhance viscosity of the digesta in the small intestine and to impair dispersion and mixing of the food mass with the fluid layer adjacent to the mucosal surface. Arabinoxylans have been implicated in a slowing of the rate of absorption of glucose and reduction of the glycemic response as well as having beneficial effects on long-term weight management. Indeed, consumption of water soluble arabinoxylan-supplemented diets was shown to reduce the postprandial glucose, insulin, and triglyceride in healthy subjects as well as those with impaired glucose tolerances (Lu et al., 2000, 2004; Zunft et al., 2004; Garcia et al., 2006, 2007). However, the exact mechanisms of these metabolic responses have not yet been fully explained (MoÈhlig et al., 2005; Garcia et al., 2007). Arabinoxylans are not digested in the small intestine but potentially provide a fermentable carbon source for micro-organisms that inhabit the large bowel. Numerous studies provided evidence that both arabinoxylans and arabinoxylooligosaccharides may enhance the growth of potentially health-promoting bacteria. Intestinal bacteria that can be successfully proliferated by poly- and oligosaccharides include many Bifidobacterium (Bi.), Bacteroides (B.), Lactobacillia, and Clostridia species. Jaskari et al. (1998) and Crittenden et al. (2002) reported that xylo-oligosaccharide preparations (DP 2-5) supported the growth of many Bifidobacterium and Bacteroides species, as well as Lactobacillus brevis, but were not fermented by E. coli, enterococci, Clostridium sp. and the majority of Lactobacillus sp. Van Laere et al. (2000) generated arabino-xylooligosaccharides with degree of polymerization (DP) 510 and doubly-branched xylose residues and observed that they were completely fermented by Bi. adolescentis, Bi. longum, and B. vulgatus. Bi. longum, Bi. adolescentis and B. ovatus were grown on intact arabinoxylans from wheat, but only B. ovatus was supported by glucuronoarabinoxylans from sorghum (Van Laere et al., 2000; Grootaert et al., 2007). Fermentation of arabinoxylans by human intestinal bacteria is related to the production of short chain fatty acids (SCFA): butyrate, propionate, and acetate, which may have cholesterol-reducing properties and other benefits. Butyrate is a preferential source of energy for colonic mucosal cells and causes differentiation of tumor cells and suppression of cell division in vitro, whereas propionate and acetate are metabolized systemically. Hopkins et al. (2003) investigated in vitro

682


breakdown of arabinoxylans by the intestinal microbiota, collected from fecal samples from children, and found a relatively high production of propionate together with acetate. GraÊsten et al. (2003) reported that in healthy humans, the pentosan bread diet increased the concentration of butyrate, whereas the inulin bread diet increased the concentration of acetate and propionate in feces. Fecal levels of SCFA only partly reflect the SCFA production in the colon, because they can be absorbed rapidly in the proximal colon. However, the authors claimed that a high fecal concentration of SCFA indicates also their high level in the distal colon, the site of most colon tumors. In addition, it was postulated that butyrate has beneficial effects on maintaining normal functions in colonocytes, and implied that pentosans are beneficial in the human large intestine (GraÊsten et al., 2003). The molecular structure of arabinoxylans as well as composition and physical form of arabinoxylan preparations seem to affect their fermentability. Waterinsoluble arabinoxylans or unsubstituted xylans are not likely to be digested by intestinal microflora. Glistù et al. (1999, 2000) and Harris et al. (2005) reported that pericarp-rich fractions obtained from rye and wheat exhibited relatively low digestibility by animals compared to endospermic or aleurone tissues. Alkali/ xylanase treatments, extrusion or other pre-processing of grain fractions improve the rate and extent of fermentation due to partial solubilization of arabinoxylans (Glistù et al., 2000; Aura et al., 2005). Water-insoluble and unfermentable portions of arabinoxylans, like other insoluble dietary fibers, increase fecal bulk and decrease the transit time through the colon, thus potentially reducing the residence time of irritants and carcinogens in the colon and alleviating constipation. The water-soluble psyllium arabinoxylans, known for their laxative and cholesterol-lowering properties (Uehleke et al., 2008), possess unique molecular features that obstruct their fermentation by the colonic bacteria and distinguish them from the extensively fermented cereal arabinoxylans (Fischer et al., 2004). Another beneficial role of arabinoxylans in the human diet might be associated with their chemo-protective and antioxidant properties due to the presence of hydroxycinnamic acids bound to these polymers. Several studies showed that feruloylated arabinoxylans in bran have strong anti-inflammatory properties, inhibit chemically induced carcinogenesis in rats and plays a role in inhibiting lipid peroxidation and low density lipoprotein (LDL) oxidation, and scavenging oxygen radicals (Adam et al., 2002; Rondini et al., 2004). The bioavailability and efficacy of the active phenolic moieties in arabinoxylans could be improved when feruloylated oligosaccharides are released from grain tissues by partial enzymic hydrolysis. Katapodis et al. (2003) demonstrated that feruloyl arabinoxylotrisaccharide (FAX3) from wheat flour had profound antioxidant activity in 2,2-diphenyl-1-picrylhydrazyl reduction assay and inhibited the copper-mediated oxidation of human LDL, whereas Yuan et al. (2005) showed that feruloylated oligosaccharides from wheat bran efficiently protected normal rat erythrocytes against hemolysis induced by free radicals under in vitro conditions.

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24 Soluble soybean polysaccharide H. Maeda, Soy Protein Processed Foods Company, Japan and A. Nakamura, Fuji Oil Co., Ltd., Japan

Abstract: Soluble soybean polysaccharide (SSPS) is a water-soluble polysaccharide extracted and refined from soybean. SSPS consists mainly of the dietary fibre of the soybean cotyledon and has relatively low viscosity and high stability in an aqueous solution. SSPS has various functions such as dispersion, stabilization, emulsification, and adhesion. Therefore, SSPS can be used not only as a dietary raw material for fibre-fortified food, but also for pharmaceutical and industrial applications as well as for many other food applications. The chemical structure, properties and applications of SSPS as a functional food ingredient are summarized. Key words: soybean, polysaccharides, structure, function, stabilizer, emulsifier.

24.1

Introduction

Soluble soybean polysaccharide (SSPS) is a water-soluble polysaccharide extracted and refined from soybean. Fuji Oil has been marketing SSPS under the brand name `SOYAFIBE-S' since 1993. SOYAFIBE-S consists mainly of the dietary fibre of soybean cotyledon and has relatively low viscosity and high stability in aqueous solution. During the manufacture of soy protein isolate, soymilk and tofu (soybean curd), òkara', which is the insoluble residue from protein extraction, is produced.1,2 Okara is a rich source of dietary fibre with reported health benefits and bowel-conditioning effects.3,4 Therefore, okara can be used as an ingredient in various types of food, including salads, soups, sauces, baked goods, desserts, sausages and okara burgers.5,6 However, most okara is still used ineffectively and is treated as industrial waste. Its difficult handling is caused mostly by its

694


high moisture content (about 80%). We started to study the high utilization of okara about 18 years ago and from the research developed the SSPS, SOYAFIBE-S. SSPS has been shown to be functional as a dispersing agent, stabilizer, emulsifier, and for its adhesion properties.7,8 Therefore, SSPS can be used not only as a source of raw materials for fibre-fortified foods, but also for pharmaceutical and industrial applications as well as for many food applications. In this chapter, the material structure, properties and applications of SSPS are introduced.

24.2

Manufacture

The water-soluble soybean polysaccharide, SSPS, derives from the cotyledon in the seed of Glycine max MERRILL. SSPS is extracted from okara, which is the insoluble material resulting from the manufacture of soy protein isolate, by heating in weak acidic conditions. The patented extraction technique is very efficient to make varieties of SSPS which differ in their physical properties and functionality, such as emulsifying or protein stabilizing. Extraction is followed by refining, pasteurizing, and spray-drying as shown in Fig. 24.1. Reports on the differences in SSPS composition depending on changes in the extraction process have already been published.9±11 No hazardous chemical material whose residue may cause any safety problems is used in the production of SOYAFIBE-S.

24.3

Structure

24.3.1 General composition Table 24.1 shows the typical composition of SOYAFIBE-S-DA100 (the most common type of SSPS). The predominant sugar components are galactose, arabinose, and galacturonic acid, but many other sugars such as rhamnose, fucose, xylose and glucose are also present. The composition is similar to that of pectins, acidic polysaccharides found in abundance in the peel of various fruits (e.g., citrus, apple). However, the amount of neutral monosaccharides in SSPS is much higher than in pectins. SOYAFIBE-S is supplied in different types, each

Fig. 24.1 The manufacturing process of SOYAFIBE-S.

Soluble soybean polysaccharide 695 Table 24.1 Moisture

Chemical composition of SOYAFIBE-S-DA100 Crude protein

Crude ash

(%)

(%)

5.8

9.2

Sugar compositionb (%)

(%)

Dietary fibre contenta (%)

Rha

Fuc

Ara

Xyl

Gal

Glc GalA

8.6

66.2

5.0

3.2

22.6

3.7

46.1

1.2

18.2

a

The analysis was conducted by AOAC official method (Prosky method).12 Neutral saccharides were analysed by GLC after being converted to alditol acetate, and galacturonic acid were by Blumenklantz method.13 b

modified to have specific functionality. For example, a type containing less than 5% residual protein is useful as a protein stabilizer under acidic conditions and also useful as an edible film or coating. 24.3.2 SSPS structure Soybean okara, which is the residue after oil and protein extraction from soybean, contains soluble and non-soluble dietary fibre from soybean cotyledon. In soluble dietary fibre from soybean cotyledon, the sugar compositions and sequences have been reported,14±17 but the full aspects of their structure are not fully known. The gel-filtration chromatographic analysis of SSPS by HPLC shows three components having approximate molecular mass of 550 kDa, 25 kDa, and 5 kDa, respectively, and the mean value is estimated to be several hundred kDa (Fig. 24.2). The chemical structure of the main component of SSPS, having the molecular mass of 550 kDa, has been clarified.18 This major component of SSPS has three types of units in the main backbone consisting of homogalacturonan and rhamnogalacturonan, composed of the diglycosyl repeating unit, -4)--D-

Fig. 24.2 Molecular mass distribution of SSPS obtained by gel permeation chromatography using refractive index and multiangle laser light scattering detection.

696


Fig. 24.3 Distribution of galacturonan region in SSPS and citrus pectin.

GalpA-(1!2)--L-Rhap-(1-. The SSPS backbone consists of long-chain rhamnogalacturonan and short-chain homogalacturonan, while citrus pectin, for example, consists of short-chain rhamnogalacturonan and long-chain homogalacturonan (Fig. 24.3). The neutral sugar side chains of -1,4-galactans (degree of polymerization = 43±47), branched with fucose and arabinose residues, and -1,3- or 1,5-arabinans are linked to the C-4 side of rhamnose residues in the rhamnogalacturonan (Fig. 24.4).19±21 The physical properties of SSPS have also been studied using static and dynamic light scattering, and a radius of gyration of the polysaccharide of about 23:5 2:8 nm was measured.22 In addition SSPS is characterized by a compact, globular structure.22

24.4

Basic material properties and characteristics

24.4.1 High dietary fibre content As shown in Table 24.1, the content of dietary fibre as measured by the AOCS official method is more than 60%. Therefore, SSPS has the same physiological functions as those of other dietary fibres. We have found that SSPS is partially metabolized and changed into organic acid by enteric bacteria and effectively shortens the gastrointestinal transit time in rats.23 24.4.2 High solubility and stable viscosity against heat, acid and salts SSPS is a non-gelling polysaccharide soluble in both cold and hot water, and shows a relatively low viscosity compared to the viscosity of other gums or stabilizers such as guar gum, allowing a highly concentrated (more than 30%) solution to be produced (Fig. 24.5).24 Furthermore, the viscosity of the solution is not significantly affected by heating, addition of acid or salts (Figs 24.6 and 24.7). These physical properties can be explained by the globular structure of SSPS in aqueous solution.

Fig. 24.4

Structure of main fraction of SSPS.

698


Fig. 24.5 Viscosity comparison of various polysaccharide solutions at 25 ëC.

Fig. 24.6 Viscosity change by heating at various pH ranges (10% SSPS aqueous solution).

Fig. 24.7

Effect of various salts on viscosity of a 10% SSPS solution at 20 ëC.

Soluble soybean polysaccharide 699 24.4.3 Excellent adhesive and film-forming property SSPS has a strong adhesive property. The adhesive strength was tested according to the JIS standard methods, K6848-1987 and K6851-1976. As shown in Table 24.2, the adhesive strength was as strong as or better than that of pullulan (which comes from Aureobasidium pullulans), a polysaccharide generally regarded as having very high adhesive strength.25 With this property, SSPS can be employed as a binder not only in dried food applications like snacks and cereals, but also in paper, wood or glass applications (Table 24.2). Its film-forming properties allow us to make colourless, transparent, water soluble, and edible films. This filmability can also be used to coat the surface of foods such as tablets and other materials. Table 24.2

Adhesive strength and material property of film

Material SOYAFIBE-S Pullulan Gum arabic

Adhesive strength (kgf/cm2)

Tensile strength (kgf/cm2)

Young ratio (kgf/cm2)

46.6 40.5 30.7

540 509 N/D*

9,730 12,800 N/D*

* The film was easily cracked not allowing the tension to be measured.

24.4.4 Antioxidative property It has been confirmed that SSPS prevents oxidation of oils and could be employed in the manufacturing of flavour oils.26 This is presumed to be due to the stabilization of free radicals by the pectic polysaccharides constituting the main component of SSPS. 27 Figure 24.8 shows the antioxidant properties of

Fig. 24.8 Antioxidative effect of SSPS on soybean oil (stored at 60 ëC).

700


SOYAFIBE-S-LA200, in a soy oil-based powdered flavour application. When compared with gum arabic (polysaccharide commonly used in the stabilization of flavour emulsions), gum arabic did not show an antioxidative effect.

24.5 Functional properties and reported use of soluble soybean polysaccharide in foods and pharmaceutical applications Table 24.3 summarizes the functional properties and applications of SOYAFIBE-S, among which dispersion stabilizing, emulsifying, and antisticking effects are outstanding. SOYAFIBE-S is supplied in a variety of types tailored for specific applications (Table 24.4). Table 24.3

Functions and applications of SOYAFIBE-S

Functions

Applications

Type of SOYAFIBE-S

Soluble dietary fibre Stabilizing effects under acidic conditions Emulsifying Emulsion stabilizing Adhesion Film-forming property

General dietary fibre-fortified foods Drinkable yoghurt, ice cream, acidic dessert, sour cream Flavour emulsion, powdered flavour, coffee cream, dressing, cleaner Edible film, coating agent, particle forming agent, snack, bakery, coating for printing rolls Various types of paint, agricultural chemicals, ceramics, cement Meringue, surfactant Various types of cooked rice and noodles Bread, cake, ham, sausage, Kamaboko (boiled fish paste), cream sauce

All types DN DA100 EN100 LN LA200

Dispersing Foam stability Anti-sticking effect Softening effect

DN RA100 DN LA200 LA200 DN DA100 LA200 DN DA100 LA200 All types

24.5.1 Stabilization of protein particles under acidic conditions Under acidic conditions, SSPS prevents protein particles from aggregating and therefore prevents settling. Compared to high methoxyl pectin (HM-pectin), the polymer most commonly used to stabilize drinkable yoghurt,28,29 what differentiates SSPS is its ability to stabilize protein particles at low pH conditions without raising viscosity. CMC (sodium carboxymethylcellulose)30 and PGA (propylene glycol alginate)31 may also be used as stabilizers in these applications. Because of their structural characteristics, these two hydrocolloids tend to give a high viscosity to the final products. By using

Soluble soybean polysaccharide 701 Table 24.4

Varieties of SOYAFIBE-S

Type

Crude protein (%)

Crude ash (%)

Viscosity (mPa/s)

SOYAFIBE-S-DN

9.2

8.6

56

SOYAFIBE-S-DA100

6.2

8.4

62

SOYAFIBE-S-LN SOYAFIBE-S-LA200

10.4 7.5

6.6 6.5

24 16

SOYAFIBE-S-EN100

8.7

7.2

71

SOYAFIBE-S-RA100

5.0

5.2

120

12.0

7.0

15

SOYAFIBE-S-HR

Characteristics

Developed as a stabilizer for protein particles under acidic conditions Improved flavour over DN For a stabilizer of protein particles under acidic conditions Developed as an emulsifier Improved flavour of SOYAFIBE-S-LN For powdering bases Improved stability of LN in suspensions Developed for flavour emulsions Excellent colour and high viscosity For cooked rice, edible films and coatings Developed as a low viscous emulsifier

SSPS acidic milk drinks with low viscosity, light taste and no sticky mouthfeel can be produced.32 Figure 24.9 shows the viscosity, rate of precipitation, and particle size of drinkable yoghurts made with SSPS or HM-pectin as a stabilizer. Acidic milk drinks prepared with SSPS show a lower viscosity than those prepared with HMpectin. In lower pH products (pH < 4.0), SSPS shows excellent stabilizing properties, while at higher pH (pH 4.4), it is less effective than HM-pectin. In other words, SSPS is suitable for acidic milk drink with lower pH and less nonfat milk solids. This function of SSPS can be applied especially to many other products, such as beverages, ice creams, desserts, etc., and provides an excellent stability and refreshing taste under acidic conditions. Furthermore, SSPS has the merit of having low reactivity with calcium, thus ensuring its full performance even if applied at an early stage of processing before fermentation. This beneficial feature allows the manufacturing process to be improved. Figure 24.10 suggests a possible stabilizing mechanism for SSPS. This mechanism is rather different from that of HM-pectin. As shown in Fig. 24.10, SSPS contains about 20% of galacturonic acid, which is located in the main backbone of a SSPS molecule. It is possible to hypothesize that the anion groups in the backbone bind to the surface of cationic protein particles, and then hydrophilic polysaccharide layers coated on the protein particles prevent aggregation by steric repulsion. This thick layer is estimated to be about 40 nm corresponding to the hydrodynamic dimensions of SSPS in water.33,34

702


Fig. 24.9 Effects of SSPS and HM-pectin on dispersion of acidic milk protein.1 1. Formulation of acidic milk drink: non-fat milk 8.0%, stabiliser 0.4%, sugar 7.0%. 2. Measured with a B type Viscometer Model BM at 10ëC (Rotor no. 1, 60rpm). 3. After each 50 gram solution has been centrifuged at 3,000G for 20 min., the supernatant was decanted and the residue was allowed to stand for 20 min. in order to remove the remaining supernatant before measurement of the extent of precipitation. Rate of precipitation = {Precipitate (g)/50 (g)} 100 (%) 4. Measured with Laser Diffraction Particle Size Distribution Analyzer (SALD-2000A, Shimadzu Corp.)

Fig. 24.10 Stabilizing mechanism of protein particles under acidic conditions.

24.5.2 Emulsifying stability Flavour emulsions are often used as a suspension at low concentrations (i.e. 0.1%) so that a colourless transparent drink can be obtained, with a pleasant taste, scent and colour. As mentioned above, gum arabic from Acacia senegal is used widely in the field of flavour emulsions by virtue of its excellent emulsifying properties.35 SSPS has an emulsifying function comparable with gum arabic, and can be used as an emulsifier and stabilizer for any emulsified foods including flavour emulsions and powdered flavours. Table 24.5 and Fig.


Formulation of flavour emulsions SOYAFIBE-S-EN100

Test no.

1

2

3

Oil phasea 20 20 20 Gum arabic ± ± ± SOYAFIBE-S-EN100 20 15 10 Glycerol 20 20 20 Water 60 65 70 sufficient sufficient sufficient Citric acidb Total a b

120

120

120

Gum arabic 4

5

6

20 20 20 30 20 15 ± ± ± 20 20 20 50 60 65 sufficient sufficient sufficient 120

120

120

Lemon oil:MCT:SAIB = 5:55:40 (Specific Gravity 1.010) To adjust pH at 4.0

24.11 show the formulation and processing steps in the manufacturing of a flavour emulsion when SSPS is used instead of gum arabic, including the changes in the ratio of the oil phase to the emulsifying agent. From the results shown in Table 24.6, it can be seen that compared with gum arabic, a smaller amount of SSPS can be employed to formulate a flavour emulsion with good suspension stability. SSPS contains glycoproteins, whose structures we presume similar to that of the Wattle Blossom Model suggested for gum arabic.36,37 The protein fraction associated with SSPS seems to be responsible for anchoring the carbohydrate moieties of the polysaccharide onto the oil/water interface.38 SSPS stabilizes the oil droplets by steric repulsion, as its hydrophilic portion creates a thick, hydrated layer of about 30 nm, which prevents the droplets from coalescing (Fig. 24.12). It is also important to mention that SSPS suppresses deterioration of flavours with its antioxidative effects on oils, as shown in Fig. 24.8.

Fig. 24.11 Preparation of flavour emulsions. 1. Dissolve polysaccharide and glycerol in water and mix completely. 2. Adjust the solution's pH at 4.0 with citric acid. 3. Pour oil phase into the solution, and mix it by homomixer at 8000 rpm for 30 min. at 35 ëC. 4. Homogenise twice at 150 kg/cm2, 35 ëC.

704


Table 24.6

Results of emulsification test SOYAFIBE-S-EN100

Test no. Water phase viscosity (mPa/sec)a Particle size (m) Heat stabilityb Clouding stabilityc

Gum arabic

1

2

3

4

5

6

1600 0.62 0.0% A

413 0.73 2.7% B

95 0.83 14.5% C

485 0.50 6.0% B

105 0.58 10.3% C

45 0.77 10.4% D

a

Measured by BM Type Viscometer at 20 ëC. Shown in the increased rate of the oil particle size in the flavour emulsions after four-week storage at 35 ëC. c Dispersed 0.1% of flavour emulsion in water containing 8.7% sugar and 0.3% citric acid, and observed clouding stability after four-week storage at 50 ëC. A; Superior, B; Good, C; Acceptable, D; Not acceptable. b

Fig. 24.12

Stabilizing mechanism of emulsion oil droplet prepared with SSPS.

24.5.3 Foam stabilizing function SSPS also has foam stabilizing properties. The stability of foams when 2% of SSPS was added to 2% aqueous solution of hydrolysed soy protein, a common foaming agent, is shown in Table 24.7, from which we can see that SSPS is more effective than -carrageenan. This property can be used for stabilizing meringue foam. 24.5.4 Anti-sticking effect of cooked rice and noodles SSPS keeps rice, such as plain rice or rice with other ingredients like pilaf, not sticky for many hours after being cooked. This means addition of SSPS can be of benefit when mixing other ingredients with cooked rice in the food-making process.39 This property is also useful for making frozen rice. Furthermore, as the rice boiled with SSPS shows a hard texture, more water can be added to the


Results of foam stability testa

Sample solution

SOYAFIBE-S -Carrageenan No additive

Foaming ratiob

Quantity added

Viscosity

(%)

(mPa/sec)

After 10 min.

After 3 hrs

0.2 0.2 ±

4.9 11.3 4.4

2.0 2.6 1.6

1.8 1.4 0.1

a

50 ml of the hydrolysed soybean protein solution was placed in a 100 ml measuring cylinder and a change was observed on standing after shaking strongly for one minute and allowing to stand. Foaming ratio = volume of foam (ml)/volume of liquid layer (ml).

b

rice on boiling, increasing the yield of cooked rice. The rice processed with SSPS maintains good texture and does not harden during cold storage, as shown in Fig. 24.13. The same property can be applied to cooked noodles. SSPS maintains the texture of cooked noodles for many hours. Just dipping the boiled noodles in SSPS aqueous solution or spraying the solution on the noodles prevents the noodles from sticking to each other for many hours. The same effect is obtained when the noodles are boiled in SSPS aqueous solution. SSPS also keeps spaghetti and chow mein not sticky for a long time without using oil. SSPS can be added directly to the sauce, causing the noodles to remain unsticky for many hours. SSPS is adsorbed on the surface of cooked rice or noodles and coats the surface. It is assumed that the driving force of adsorption is the galacturonan of the main backbone in SSPS and the thickness of the coating layer of SSPS is the cause of the anti-sticking effect (Fig. 24.14).

Fig. 24.13 Change in the taste value of boiled rice, stored at 10 ëC. Rice was boiled with 1.2 times of water in no additive case. On the other hand, where SOYAFIBE-S was added, rice was boiled with 1.44 times of water containing 1.0% of SOYAFIBE-S for the rice. The boiled rice was stored at 10 ëC for 48 hours and the change in the taste value was analysed by the Rice Taste Analyzer STA-1A (Satake Corporation).40

706


Fig. 24.14 Coating phase of SSPS on the surface of cooked noodles observed by a fluorescence microscope. The noodle was immersed in the solution of SSPS-DA 100 pyridylamidated previously, and stored at 4 ëC for 24 h. The noodle was then observed by fluorescence microscope.

24.5.5 Other applications SSPS is a dietary fibre and can be used for a fibre enrichment in various foods. Many other applications are possible, such as a film coating agent for tablets and softener of baked foods. Thus, it may be useful not only in various foods, but also in various industrial applications. SSPS can stabilize dispersions of inorganic particles in a similar way to protein particles under acidic conditions. Therefore, applications as a dispersion agent for water colour, ceramics, and cement are possible.

24.6

Regulatory status

In Japan, SSPS is classified both as a food ingredient and food additive with no limitation of application. It must be labelled as `soybean polysaccharide' or `soybean hemicellulose' as a food additive, according to supplement 3 of the Food Sanitation Law 1996. On the other hand, it can be labelled as `soybean fibre' for use as a food ingredient. In the USA, SSPS has the status of self-affirmed GRAS.

24.7 1.

References

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and STEINKE, F. H. Èffects of soy polysaccharide on gastrointestinal functions, nutrient balance, steroid excretionms, glucose tolerance, serum lipids, and other parameters in humans', Am. J. Clin. Nutr., 1983 38 504±11. TAKAHASHI, T., EGASHIRA, Y., SANADA, H., AYANO, Y., MAEDA, H. and TERASHIMA, M. Èffects of soybean dietary fiber on growth rate, absorption and gastrointestinal transit time in rats', J. Jpn. Soc. Nutr. Food Sci. (in Japanese), 1992 45 277±84. SHURTLEFF, W. and AOYAGI, A. The Book of Tofu, Berkeley, CA, Ten Speed Press, 1975. SHURTLEFF, W. and AOYAGI, A. Tofu and Soymilk Production, Lafayette CA, The Soyfoods Center, 1984. MAEDA, H. `Development and application of soybean polysaccharides', Shokuhin to Kaihatsu (in Japanese), 1992 27 47±9. MAEDA, H. `Soluble soybean polysaccharide: properties and application of SOYAFIBE-S', The Food Industry (in Japanese), 1994 37(12) 71±4. YOSHII, H., FURUTA, T., MAEDA, H. and MORI, H. `Hydrolysis kinetics of okara and characterization of its water-soluble polysaccharides', Biosci. Biothec. Biochem., 1996 60(9) 1406±9. FURUTA, H., TAKAHASHI, T., TOBE, J., KIWATA, R. and MAEDA, H. Èxtraction of watersoluble soybean polysaccharide under acidic conditions', Biosci. Biothec. Biochem., 1998 62(12) 2300±5. MORITA, M. `Polysaccharides of soybean seeds: Polysaccharide constituents of hotwater-extract fraction of soybean seed and an arabinogalactan as its major component', Agr. Biol. Chem., 1965 29 564±73. PROSKY, L., ASP, N. G., FURDA, I., DEVRIES, J. W., SCHWEIZER, T. F. and HARLAND, B. F. `Determination of total dietary fiber on foods and food products: collaborative study', J. Assoc. Off. Anal. Chem., 1985 68 677±9. BLUMENKRANTZ, N. and HANSEN, G. A. `New method for quantitative determination of uronic acids', Annal. Biochem, 1973 54 484±9. ASPINALL, G. O., COTTRELL, I. W., EGAN, S. V., MORRISON, I. M. and WHYTE, J. N. C. `Polysaccharides of soybean. Part IV', J. Chem. Soc. (C), 1967 14 1071±80. KAWAMURA, S. À review on the chemistry of soybean polysaccharides', Nippon Shokuhin Kaugyo Gakkaishi (in Japanese). 1967 14 514±23. KIKUCHI, Y. and SUGIMOTO, H. `Detailed structure of acidic polysaccharide in soy sauce, confirmed by use of two kinds of purified pectinase', Agric. Biol. Chem., 1976 40 87±92. LABAVITCHI, J. M., FREEMAN, L. E. and ALBERSHEIM, P. `Structure of plant cell walls', J. Biol. Chem., 1967 25 5904±10. NAKAMURA, A., FURUTA, H., MAEDA, H., NAGAMATSU, Y. and YOSHIMOTO, A. `The structure of soluble soybean polysaccharide', Hydrocolloids: Part 1 (Ed. K. Nishinari) Elsevier Science, 2000 235±41. NAKAMURA, A., FURUTA, H., MAEDA, H., NAGAMATSU, Y. and YOSHIMOTO, A. Ànalysis of structural components and molecular construction of soybean soluble polysaccharides by stepwise enzymatic degradation', Biosci. Biotech. Biochem., 2001 65(10) 2249±58. NAKAMURA, A., FURUTA, H., MAEDA, H., TAKAO, T. and NAGAMATSU, Y. Ànalysis of the molecular construction of xylogalacturonan isolated from soluble soybean polysaccharides', Biosci. Biotech. Biochem., 2002 66(5) 1155±58. NAKAMURA, A., FURUTA, H., MAEDA, H., TAKAO, T. and NAGAMATU, Y. `Structural studies TSAI, A. C., MOTT, E. L., OWEN, G. M., BENNICK, M. R. LO, G. S.

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22.

23. 24. 25. 26. 27. 28. 29. 30. 31. 32.

33. 34. 35. 36. 37. 38.

Handbook of hydrocolloids by stepwise enzymatic degradation of the main backbone of soybean soluble polysaccharides consisting of galacturonan and rhamnogalacturonan', Biosci. Biotech. Biochem., 2002 66 (6) 1301±13. WANG, Q., HUANG, X., NAKAMURA, A., BURCHARD, W. and HALLET, F. R. `Molecular characterization of soybean polysaccharides: an approach by size exclusion chromatography, dynamic and static light scattering methods', Carbohydr. Res. 2005 340 2637±44. TAKAHASHI, T., MAEDA, H., AOYAMA, T., YAMAMOTO, T. and TAKAMATSU, K. `Physiological effects of water-soluble soybean fiber in rats', Biosci. Biothec. Biochem. 1999 63(8) 1340±5. FURUTA, H. and MAEDA, H. `Rheological properties of water-soluble soybean polysaccharides extracted under acidic condition', Food Hydrocolloids, 1999 13 267±74. NAKAMURA, S. `Function and application of pullulans', Fragrance Journal (in Japanese), 1986 78 69±74. MATSUMURA, Y., EGAMI, M., SATAKE, C., MAEDA, H., TAKAHASHI, T., NAKAMURA, A. and MORI, T. Ìnhibitory effects of peptide-bound polysaccharides on lipid oxidation in emulsions', Food Chemistry, 2003 83 107±19. YOSHIKI, Y. and OKUBO, K. `Chemiluminescence of DDMP saponin and Chemiluminescence substance in soy sauce', Syushi Seiriseikagaku Kenkyukai Youshisyu (in Japanese), 1994 15 26. GLAHN, P. E. `Hydrocolloid stabilization of protein suspensions at low pH', in: Prog Fd Nutr Sci 6, Phillips, G. O., Wedlock, D. J. and Williams, P. A., eds, Oxford, Pergamon Press, 1982, 171±7. PEDERSEN, H. C. A. and JORGENSEN, B. B. Ìnfluence of protein on the stability of casein solutions studied in dependence of varying pH and salt concentration', Food Hydrocolloids, 1991 5 323±8. ANON. `Develops milk-orange juice', Food Eng., 1971 Apr 97±101. LUCK, H. and GROTHE, J. `Fruit juice-flavored milk', S. Afr. J. Dairy Technol., 1973 5 47±52. ASAI, I., WATARI, Y., IIDA, H., MASUTAKE, K., OCHI, T., OHASHI, S., FURUTA, H. and MAEDA, H. Èffect of soluble soybean polysaccharide on dispersion stability of acidified milk protein', in Food Hydrocolloids Structure, Properties, and Functions, Nishinari, K., and Doi, E., eds, New York, Plenum Press, 1993. NAKAMURA, A., FURUTA, H., KATO, M., MAEDA H. and NAGAMATSU, Y. Èffect of soluble soybean polysaccharides on the stability of milk protein under acidic conditions', Food Hydrocolloids, 2003 17(5) 333±43. NAKAMURA, A., YOSHIDA R., MAEDA, H. and CORREDIG, M. `The stabilizing behavior of soybean soluble polysaccharide and pectin in acidified milk beverages', Int. Dairy J. 2006 16 361±69. TAN, C. T. and HOLMES, J. W. `Stability of beverage flavor emulsions', Perfumer and Flavorist, 1988 13 Feb/Mar 23±41. CONNOLLY, S., FENYO, J. C. and VANDE WELDE, M. C. `Heterogeneity and homogeneity of an arabinogalactan-protein: Acacia senegal gum', Food Hydrocolloids, 1987 1 477±80. RANDALL, R. C., PHILLIPS, G. O. and WILLIAMS, P. A. `The role of proteinaceous component on the emulsifying properties of gum arabic', Food Hydrocolloids, 1988 2 131±40. NAKAMURA, A., YOSHIDA, R., MAEDA, H., FURUTA, H. and CORREDIG, M. À study of the

Soluble soybean polysaccharide 709 role of the carbohydrate and protein moieties of soy soluble polysaccharides in their emulsifying properties', J. Agric. Food Chem. 2004 52 5506±12. 39. FURUTA, H., NAKAMURA, A., ASHIDA, H., ASANO, H., MAEDA, H. and MORI, T. `Properties of rice cooked with commercial water-soluble soybean polysaccharides extracted under weakly acidic conditions from soybean cotyledons', Biosci. Biotech. Biochem. 2003 67(4) 677±683. 40. MIKAMI, T. `Machine design and development for rice other grains in chugoku area (Development of rice taste analyzer)', Sekkei Kougaku (in Japanese), 1997 32 113± 19.

25 Cellulosics J. C. F. Murray, UK

Abstract: The range of cellulosics approved for food applications is reviewed. These are methyl cellulose (mc), hydroxypropyl cellulose, hydroxypropyl methyl cellulose, methyl ethyl cellulose and carboxymethyl cellulose (cmc). Manufacture, structure, properties and regulatory status are summarised. A range of applications is discussed for each cellulosic, including mc applications using thermal gelation properties, and cmc applications involving thickening and involving protein stabilisation at reduced pH levels. Key words: cellulosics, methylcellulose, carboxymethyl cellulose, applications.

25.1

Introduction

Cellulose is probably the most abundant organic substance existing in nature and is the major constituent of most land plants. It is the starting material for a wide range of modifications with uses both in the food industry, and an even greater variety of uses outside this sector. Cellulosics, as used in this chapter, covers the range of modified celluloses generally approved as food additives. These are methyl cellulose E461, hydroxypropyl cellulose E463, hydroxypropyl methyl cellulose E464, methyl ethyl cellulose E465, and sodium carboxymethyl cellulose E466 which is frequently called simply carboxymethyl cellulose and also known as cellulose gum. The respective abbreviations mc, hpc, hpmc, mec and cmc are widely used. Properties of modified celluloses such as hydroxyethyl cellulose, which do not have approval for food additive use, are not included in this chapter. The common feature of all of these additives is that they are hydrocolloids derived from cellulose raw material by chemical modification. Since there are

Cellulosics 711 many points which are common to this range of additives, and to avoid repetition, where appropriate topics will be covered as a class rather than as the individual additives.

25.2

Manufacture

25.2.1 Raw material The raw material for modified celluloses is cellulose pulp, which in turn is produced from wood pulp from specified species or from cotton linters. Cotton linters are the short fibres from the cotton ball, which are too short to be suitable for use in thread and weaving. The polymer chain length of cellulose varies with the different raw materials and hence the polymer length and the resultant viscosity required in the final product will govern the selection of the raw material. 25.2.2 Manufacturing process In general terms, cellulose pulp is dispersed in alkali solution to form alkali cellulose and is then treated with appropriate reagents, under tightly controlled conditions, to substitute the anhydroglucose monomers of the cellulose chain. The substitution is at the hydroxyl groups and the substitution reagents are as follows: · · · · ·

methyl cellulose ± chloromethane hydroxypropyl cellulose ± propylene oxide methyl hydroxypropyl cellulose ± mixed substituents as above methylethyl cellulose ± chloromethane and chloroethane mixed substituents carboxymethyl cellulose ± monochloracetic acid.

The two stages of the reactions can be summarised as follows: 1. 2.

Cellulose + Alkali + Water Alkali cellulose + R±X Alkali cellulose + R±CH(O)CH2 Alkali cellulose + X±R±COOH

! ! ! !

Alkali cellulose Alkyl cellulose Hydroxyalkyl cellulose Carboxyalkyl cellulose

The substitution reaction is followed by purification and washing stages to remove by-products and to achieve the purity levels specified for food additives.

25.3

Structure

The structure of the cellulose molecule is shown in Fig. 25.1. It is shown as a polymer chain composed of two repeating anhydroglucose units ( glucopyranose residues) joined through 1,4 glucosidic linkages. In this structure, n is the number of anhydroglucose units or the degree of polymerisation.

712


Fig. 25.1

Fig. 25.2

Structure of cellulose.

Idealised unit structure of cellulose gum, with a ds of 1.0.

Each anhydroglucose unit contains three hydroxyl groups, which in theory can be substituted. The average number of hydroxyl groups substituted per anhydroglucose unit is known as the degree of substitution (ds). Without exception, the ds required to produce desirable properties is much below the theoretical maximum. In the example in Fig. 25.2, carboxymethyl cellulose with ds 1.0 is shown.

25.4

Properties

25.4.1 General There are three main factors, which influence the properties of modified celluloses. These are first, and most importantly, the type of substitution of the cellulose, secondly, the average chain length or degree of polymerisation of the cellulose molecules (dp) and thirdly, the degree of substitution of the chain. Additionally, the particle size of the hydrocolloid may be varied. Particle size and powder bulk density affect the dissolving characteristics of the product. Granular material is less prone to clumping or balling but takes longer to dissolve. Fine powdered material can give very rapid hydration, but does not disperse so easily and good stirring or blending techniques are necessary. Degree of polymerisation is a measure of the chain length of the polymer. Increasing dp very rapidly increases the viscosity of the modified cellulose in solution, although the viscosities of two differently substituted modified celluloses of comparable dp will not necessarily be comparable.

Cellulosics 713 In general the modified celluloses give neutral-flavoured, odourless and colourless clear solutions. It should be noted that all modified celluloses, in powder or even granular form, are capable of absorbing water from the atmosphere. It is therefore desirable to store these products in airtight packs. 25.4.2 Methyl cellulose and hydroxypropyl methyl cellulose The properties of these two hydrocolloids are very similar and will be covered together. Mc and hpmc are both soluble in cold water to give solutions with a wide range of viscosity, which is dependent on both dp and ds. These solutions show reasonable viscosity stability over the range pH 3±11. More important, however, is the behaviour of solutions on heating since the solution will change into a gel once the temperature of the solution has been raised above a point known as the incipient gel temperature (igt). The igt varies from 52 ëC for mc, to a range of 63±80 ëC for hpmc types with increasing degree of hydroxypropyl substitution increasing the igt. These gels are reversible on cooling although there is a pronounced hysteresis between heating and cooling. Both polymers are good film formers and also exhibit some surface activity. Commercially mc and hpmc are distinguished by viscosity in 2% aqueous solutions, and also by the ds. 25.4.3 Hydroxypropyl cellulose Hpc is also soluble in cold water and again a range of viscosity can be obtained dependent on dp. Hpc becomes insoluble at temperatures above approximately 45 ëC but unlike mc and hpmc, no gel is formed. Hpc is unusual in food hydrocolloids in that it is soluble in ethanol and mixtures of ethanol and water. However, the most interesting properties of hpc are probably its good film formation and its high surface activity compared to most other hydrocolloids. Commercially, the various grades of hpc for food use are differentiated by viscosity. 25.4.4 Methylethyl cellulose In common with mc or hpmc, mec is also soluble in cold water and forms gels on heating, albeit weak gels, above the igp. These properties alone would not justify great interest in mec as a food additive, rather it is its surface activity and consequent excellent performance as a whipping aid, particularly in the presence of protein, which are of technical use. 25.4.5 Carboxymethyl cellulose General Cmc is soluble in both hot and cold water to give clear and colourless solutions with neutral flavour. As with other modified celluloses, the solution viscosity depends on dp, but it is possible to produce 1% aqueous solutions with viscosity

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of 5,000 mPas at ambient temperatures. These solutions do show a reversible reduction of viscosity on heating but in food systems do not gel either alone or with other hydrocolloids. The rate of viscosity build-up is obviously dependent on dp, particle size and to some extent on ds. With suitable fine grind powders an extremely rapid viscosity development can be obtained. A maximum degree of substitution of 1.5 is permitted in a recent amendment to EU legislation, but more typically ds is in the range 0.6±0.95 for food applications. ds, together with the uniformity of substitution, affects the rheology of the solution. Solutions of lower ds are thixotropic, whereas higher ds tends to pseudoplasticity. Uniformity of substitution favours pseudoplastic rheology, and solutions of such types give a particularly `smooth' mouthfeel. Commercially, cmc types are distinguished by viscosity, by particle size and to a more limited extent by ds and special solution characteristics. It is necessary to check the concentration of the solutions for which viscosities are specified, as there is not a single standard value for concentration. Interaction of cmc with proteins Cmc is an ionic polymer and this allows the formation of complexes with soluble proteins such as casein and soy at, or around, the isoelectric region of the protein. Although the effect on the system is primarily dependent on pH, it is also dependent on the composition and concentration of the protein, temperature, and the concentration and type of the cmc. At pH less than 3.0 or higher than 6.0, cmc reacts in the cold with the proteins in milk to form a complex, which can be removed as a precipitate. In the pH range approximately 3.0±5.5, a stable complex is formed. At the maximum of stability the viscosity is abnormally high compared to the individual components. A representation of the effects of pH on the viscosity of a solution of cmc and casein is shown in Fig. 25.3. The system containing the cmc and casein complex is relatively shear sensitive, and the viscosity decreases under agitation. The complex is heat stable and little viscosity decrease is observed on heating. The casein is denatured to a much smaller extent than would be the case in the absence of cmc.

25.5

Applications

25.5.1 Methyl cellulose and hydroxypropyl methyl cellulose The major applications of these two hydrocolloids are in the fields of binding and shape retention, film formation and barrier properties, and avoidance of boil-out and bursting at higher temperatures. The thermogellation properties of mc and hpmc can be used to bind and to give shape retention to products where the ingredients themselves do not have particularly good biding properties. This includes such categories as reformed vegetable products such as potato croquettes and waffles, onion rings and the whole range of shaped soya protein and similar vegetarian products. These have

Cellulosics 715

Fig. 25.3

Viscosity effect of CMC-casein complex at varying pH.

poor binding properties and a tendency to disintegrate on heating due to the disruptive effects of steam formed during heating. Inclusion of hpmc, or better, mc means that on heating above the igp the hydrocolloid will gel and bind the ingredients of the product. Because the gelation is thermoreversible and the gel has reverted to solution form at temperatures above normal eating temperatures, no alteration in texture from gelation is observed by the consumer. Two examples of applications of this type are given in Formulations 25.1 and 25.2. In each of these cases the hydrocolloid is added to the cold mix in order that it may hydrate. Neither mc nor hpmc will hydrate in hot water above the igp, a property that can be used to ensure good dispersion of the gum if it is necessary to produce solutions and good stirring is not available. The use of thermogelation properties to inhibit boil-out in is shown in Formulation 25.3. This is a bakery filling, but the principle is valid for sauces and other fillings where boil-out needs to be avoided. In this case the dry Formulation 25.1

Potato croquettes

Ingredients Mashed potato Potato flake Salt BenecelÕ hpmc type MP852 Water

Composition (%) 79 11 1 0.5 to 100

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Formulation 25.2

Soya burgers

Ingredients

Composition (%)

Soya protein Vegetable fat Starch Potato flour Benecel type M043 methyl cellulose Dried onion Salt Seasonings and flavours Water Formulation 25.3

21 15 2 2 2 1.5 1 0.5 to 100

Bake-stable filling

Ingredients Sugar Pregelatinised modified starch Skimmed milk powder Whole milk powder Benecel type M043 methyl cellulose Disodium phosphate Flavour and colour Water

Composition (%) 13 5 4 3.5 0.5 0.15 to taste to 100

ingredients are blended and mixed cold with the water to permit satisfactory solution of the methyl cellulose, and after standing 60 minutes the filling is baked. In cases where the sauce or filling is heat-treated prior to storage, care must be taken in the choice of addition point of the mc or hpmc, otherwise the dissolved hydrocolloid in the product will gel in the heat-processing equipment. A solution to this problem is to disperse the hydrocolloid in the hot product, where it will not dissolve until the heating stages are complete and the product is cooled below the igp. The thermogellation properties will then be exhibited at the next heating cycle. The same thermogelling binding properties are utilised in batter and coating mixes. Low or medium-low viscosity grades are used at levels of up to 1% to improve adhesion and also to reduce oil or fat absorption. This application could also be said to utilise film formation properties, and film formation also contributes to the reported use of these additives in providing reduced oil uptake when deep frying such products as seafood and potatoes. Coating is normally effected by dipping or spraying a solution of the cellulosic, followed by drying. 25.5.2 Hydroxypropyl cellulose To an extent, hpc is still a product waiting for applications in the food industry. The good surface activity of hpc is exploited in use of lower viscosity grades of

Cellulosics 717 Formulation 25.4

Topping for whipping

Ingredients Vegetable oils or fats Milk protein KlucelÕ hydroxypropyl cellulose type GF Emulsifiers Sugar or glucose syrup Salt, flavour and colour Water

Composition (%) 20±35 1±4 0.2±0.3 0.4±1.0 6±20 to taste to 100

hpc in toppings for whipping or dispensing from aerosol cans. Toppings stabilised with hpc retain the whipped structure at high ambient temperatures and in this respect are considered superior to other hydrocolloids. Use levels are typically 0.2±0.3% of the topping. A recipe example is given in Formulation 25.4. Hpc is soluble in ethanol and gives clear solutions in aqueous ethanol when the ethanol concentration is under approximately 50%. This gives potential for variations in viscosity or mouthfeel in a wide range of alcoholic beverages. It also has good film-forming properties and these films exhibit good flexibility, good oil and air barrier properties and a lack of tackiness. These properties have been examined in the pharmaceutical industry and may have potential in the speciality confectionery sector. 25.5.3 Methyl ethyl cellulose The major use of mec has been in foam formation and stabilisation. Solutions of mec can be whipped to produce a fine foam with an over-run comparable to egg white. The solutions can be re-whipped even if the foam is allowed to return to liquid after standing. Importantly, mec foams are compatible to many common food ingredients including egg white and fat. This has made it suitable for toppings, mousses, batters and the like. 25.5.4 Carboxymethyl cellulose General Since viscosity production is the primary property of cmc, this review will start with applications where viscosity is the major property required. In such cases it is normal to use high viscosity grades of cmc, partly for economic reasons as cmc prices are based more on the quantity of the gum than on the amount of viscosity developed. Additionally, the lower concentrations of gums required with high viscosity grades, compared to medium or lower viscosity grades, produce more acceptable and less gummy mouthfeel. A range of granulometries is available. Although the standard particle size will be suitable in many applications, the coarser particles will be preferred when it is necessary to make up solutions with poor mixing equipment, and the

718


thirty minutes stirring necessary to dissolve this particle is not a problem. On the other hand, extra fine powders will be necessary for vending mixes and other instant applications. In these applications cmc will normally give a more rapid viscosity build up than guar gum. Instant products With instant products such as vending drinks and powdered drink mixes fine grind cmc is used to provide the required rapid build-up of viscosity. If high viscosities are required and consequently high cmc concentrations are used, there may be a perception of a `gummy' mouthfeel. This can be reduced or eliminated by use of evenly substituted types with smooth flow properties, such as BlanoseÕ cmc type 7H3SXF. Some examples of cmc use in both cold and hot instant products are given in Formulations 25.5 and 25.6, illustrating that cmc has both hot and cold viscosity. The first formulation shows use of the high viscosity type Blanose cmc 7HXF, but this could be substituted by the Blanose cmc type 9M31XF at approximately twice the use level. Frozen products The viscosity produced by cmc contributes to the stabilisation of frozen products such as ice cream, water ices and ripples. Benefits observed include the Formulation 25.5

Instant fruit drink powder

Ingredients Fine sugar Citric acid Sodium citrate Clouding agent BlanoseÕ cmc type 7HXF Flavour and colour Powder Water Drink Formulation 25.6

% of powder

% of drink

89.45 6.50 2.45 0.80 0.80 to taste 100

10.55 0.75 0.30 0.10 0.10 88.2 100

Instant chocolate drink

Ingredients Skimmed milk powder Sugar Cocoa powder Blanose cmc type 7H3SXF Total powder Water for 5:1 dilution

% of powder

% of drink

53.5 36.0 9.75 0.75 100.0

8.9 6.0 1.6 0.13 16.6 83.4

Cellulosics 719 Formulation 25.7

Water ice or ripple

Ingredients

Water ice (%)

Sucrose Dextrose Blanose cmc type 7HOF Fruit juice Citric acid Flavour and colour Water Formulation 25.8

25 7 0.25 0.4 to taste to 100

Ripple syrup (%) 30 0.75 40 0.3 to taste to 100

Ice cream

Ingredients Milk fats Milk solids non fat Sucrose Glucose syrup Emulsifier Blanose cmc type 7HXFMA GenulactaÕ carrageenan type L-100

Composition (%) 12 11 12.5 4 0.1 0.17 0.03

conservation of texture and inhibition of ice crystal formation, a slow meltdown and an improved resistance to dripping. Where products such as water ices have a low pH it may be desirable to use a cmc which tolerates acidic conditions without loss of viscosity, such as Blanose cmc type 7HOF (Formulation 25.7). Cmc can also be used as the primary stabiliser in ice cream to control ice crystal size and growth during freeing and storage, to provide a smooth eating texture and to provide heat shock resistance (Formulation 25.8). When compared to locust bean gum or guar gum, there is a higher over-run which means that cmc is particularly suitable for use in soft serve products. Use of cmc tends to produce whey separation, but this can be avoided by use of carrageenan together with cmc in a ratio of about 1:6. Table sauces and dressings The thickening effects of cmc can be used in products such as salad dressings and tomato sauces. Properties of cmc which make it suitable for these applications include its rapid solubility in both hot or cold water, its good water binding and good tolerance to low pH levels. In salad dressings, typical use levels would be 1.0% Blanose cmc type 7HOF when oil contents are 30% and 0.75% when oil contents are increased to 50%. Tomato sauce or tomato ketchup is a further application for cmc, and is particularly interesting because variation of the cmc type can be used to vary the structure of the product. In Formulation 25.9, type 7HOF can be used for a long-

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Formulation 25.9

Ketchup

Ingredients Tomato concentrate (28%) Sugar Salt Citric acid and vinegar (to pH 3.7±3.9) Blanose cmc type 7HXFMA Blanose cmc type 7HOF Preservative Water

Compositions (%) 40.0 20.0 1.5 7.5 1.1 0.2 44.7

40.0 20.0 1.5 7.5 0.9 0.2 44.9

Note: If tomato concentrate levels are increased to 40%, then the cmc levels can be halved to around 0.5%.

structured ketchup, while type 7HXFMA will provide a much pulpier and shorter textured product. Soft drinks The viscosifying properties of cmc are widely used in ready-to-consume soft drinks. Additional body or mouthfeel can be provided to low calorie drinks sweetened with intense sweeteners, to more closely match the mouthfeel obtained with sucrose or glucose syrup. Use levels are typically 0.025±0.5% of the drink. Cmc is widely used to suspend fruit pulp and to inhibit `neck ringing' by flavour oils in fruit squashes and other dilutable soft drinks and in ready-to-consume drinks containing fruit pulp. This has become more necessary as manufacturers have substituted intense sweeteners for a part of the bulk sweeteners. Generally, the concentration of Blanose cmc type 7HOF will be 0.05±0.1% of the fruit squash or ready-to-consume drink depending on the exact composition and density of the drink. Medium viscosity cmc types such as Blanose type 9M31F are used at approximately twice the addition level. Since cmc develops its viscosity more effectively if dissolved in water before addition of either acids or bulk sweeteners, it is good practice to produce a 1% stock solution of high viscosity types which can then be added as required. Bakery products A further application where viscosity development is required is in cake mixes and batter mixes. Incorporation of cmc can improve the volume yield of certain doughs as a result of its viscosity drop during baking and improves the suspension and distribution of ingredients such as dried fruit. Additional water is required in comparison to recipes without cmc, and so results in increased yields and improved moistness, particularly after storage. The fine grind types will normally be used in bakery mix concepts. In this case not only is the granulometry more compatible with flour, but also the fine grind allows a better water absorption in competition with other components such flour and sugar (Formulation 25.10).

Cellulosics 721 Formulation 25.10 Fruit cake mix Ingredients Flour Sugar Fat Baking powder Blanose cmc type 7H4XF Eggs Water (additional to control)

Composition (%) 37 31 31 0.6 0.3 31 5

Some speciality cmc types have particularly good water binding properties, although their solution properties may be comparatively poor. This excellent water binding is utilised in baked products, including breads and morning goods, to either increase yield or to retard staling and hence improve consumer acceptability and prolong shelf life. The effect is compatible with other bread additives and improvers. Use of AquasorbÕ cmc type A-500 at levels of 0.5±1.5%, and normally 0.5±1.0%, of flour weight is recommended in this type of application. The water binding effect of these cmc types can also be used to reduce the fat absorption of doughnuts during cooking. The improved water binding is believed to inhibit fat absorption. Use levels of up to 0.3% are quoted. Low pH milk products Due to its ionic nature, cmc can react with soluble proteins to form a complex at or around the isoelectric point of the protein. In a sour milk medium at pH3.8± 5.0, cmc reacts with casein to form a soluble complex, stable to heat treatment and to storage. In practice this effect is best utilised in the higher part of this pH range since at pH below about 4.2 there tends to be too great variation in viscosity with even small changes in pH. At pH levels 4.3±3.8 pectin is frequently the preferred stabiliser, although even at these levels cmc is sometimes used if economy is of prime importance. Examples of low pH milk preparations are given in Formulations 25.11 and 25.12. Formulation 25.11 Buttermilk drink pH4.5±4.6 Ingredients Buttermilk Sugar Blanose cmc type 7HOF

Composition (%) 89.6 10 0.3±0.4

Preparation 1. Blend the sugar and cmc and add this blend gradually into the buttermilk while stirring rapidly. Continue stirring for 15 minutes. 2. Heat up to 70 ëC in a heat exchanger. 3. Homogenise to 150 to 200 bar. 4. Pasteurise at 85 ëC for 15 seconds. 5. Cool to 20 ëC and fill aseptically if extended shelf life is required.

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Formulation 25.12 Milk orange juice beverage at pH4.5±4.6 Ingredients Whole milk Orange juice (11ë Brix) Sugar Blanose cmc type 7HOF

Composition (%) 53.8 41.3 4.7 0.15±0.20

Preparation 1. Blend the cmc and sugar and add the blend to the cold milk with stirring. 2. Stir until the cmc is fully dissolved (15 minutes with good agitation). 3. Slowly add the orange juice, cooled to 10 ëC or lower, to the milk while stirring well. 4. Continue to stir for at least five minutes after the end of juice addition. 5. Heat to 70 ëC in a heat exchanger. 6. Homogenise at 150±200 bar. 7. Pasteurise at 85 ëC for 15 seconds. 8. Cool to 20 ëC and fill.

25.6

Regulatory status

25.6.1 Names and serial numbers In the member states of the European Union, use of the modified celluloses described in this chapter is permitted by Directive 95/2/EC on food additives other than colours and sweeteners. National legislation in the individual member states implements this directive. The EU directive has assigned names and serial numbers (E numbers) to these additives as follows: · · · · ·

E461 E463 E464 E465 E466

methyl cellulose hydroxypropyl cellulose hydroxypropyl methyl cellulose methyl ethyl cellulose carboxymethyl cellulose or sodium carboxymethyl cellulose.

It is hoped that in the future the style `modified cellulose', which is already permitted in other jurisdictions, will also be permitted in EU member states. The directive sets specifications for these additives when they are to be used in food applications. These specifications cover such matters as purity, permitted degree of substitution, molecular weights and moisture levels for each individual additive, but detailed discussion of specifications is outside the scope of this chapter. Food industry users of modified celluloses should be aware that in general there is a greater use of these products in other classes of industry, where specifications are to lower standards of purity, and checks should always be made that food specification material is being used. For example, cmc for food use has a minimum purity level of 99.5% cmc, whereas technical grades are commonly sold at only 98.0% purity or lower.

Cellulosics 723 25.6.2 Permitted use levels All these additives are placed in Annex I of the directive, which permits their use at `quantum satis' level in products other than those where there are specific regulations on composition. These specific exceptions are listed in Annexes VI, VII and VIII, but these limited exceptions will not be detailed. The term `quantum satis' means that no maximum level of the additive in or on a food is specified but in or on a food the additive may be used in accordance with good manufacturing practice at a level not higher than is necessary to achieve the intended purpose and provided that such use does not mislead the consumer. Outside Europe, use of modified celluloses is also permitted under purity criteria set by the Food and Agriculture Organisation and the Wold Health Organisation (FAO/WHO) and the US Food Chemicals Codex. In the United States use of modified celluloses is allowed in a wide range of foods, and this is true in many other countries. However, space does not permit a detailed review of the legislative situation in every country, and specialised advice should always be sought in case of doubt. The Joint FAO/WHO Expert Committee on Food Additives (JECFA) assigned in 1990 an Acceptable Daily Intake (ADI) `not specified' to the modified celluloses. 25.6.3 Ingredient declarations In EU member states there is an approved manner to label foodstuffs where an additive is used and has a technological effect in the foodstuff. The additive should be described on the foodstuff package ingredient label as `thickener' or `stabiliser' or `gelling agent' as appropriate, followed by the serial number (Enumber) or the approved name as given in Section 25.6.1. There is no legal requirement to include processing agents in the ingredient declaration of a foodstuff.

26 Bacterial cellulose J. K. Park, Kyungpook National University, Korea, J. Y. Jung, Korea Institute of Patent Information (KIPI), Korea and T. Khan, COMSATS Institute of Information Technology, Pakistan

Abstract: Bacterial cellulose consists of an ultra-fine network of cellulose nanofibers (3±8 nm) which are highly uniaxially oriented. This type of 3D structure results in a higher crystallinity (60±80%) of bacterial cellulose and tremendous physico-chemical and mechanical properties. This chapter deals with a comprehensive description of the cellulose synthesized by microbial cells. The introduction gives a brief account of the various aspects of bacterial cellulose. Sections 26.2 and 26.3 present a concise historical outline of the evolution of bacterial cellulose from its discovery to its use in the modern day advanced functional materials. Section 26.4 provides a description of the process(s) currently used in the manufacture of bacterial cellulose. Section 26.5 provides a discussion of the physico-chemical structure of bacterial cellulose. Section 26.6 describes the physicomechanical properties of bacterial cellulose with special attention to those distinguishing it from plant cellulose. Section 26.7 focuses on the detailed description of the uses and applications of bacterial cellulose in various fields. Special emphasis will be given to its applications in the food industry. Section 26.8 includes the various regulations related to the use of bacterial cellulose as a drug, a food or formulations thereof. Key words: bacterial cellulose, Acetobacter, Rhizobium, Agrobacterium, Gluconacetobacter, Sarcina, cellulose-negative (Cel±) mutant, shear stress, cellulose synthase operon, static cultivation, agitated culture, membrane, glucuronic acid, crystalline structures, thickener, stabilizer, texture modifier, audio component, wound dressing.

Bacterial cellulose

26.1

725

Introduction

Cellulose, a homopolymer composed of -(1,4) glucose, is the most abundant biopolymer in nature. It is the major component of the cell walls of nearly all plants, fungi and some algae. Cellulose can also be produced by some bacterial strain belonging to the genera Acetobacter, Rhizobium, Agrobacterium, and Sarcina (Delmer, 1999; Brown 1886; Embuscado et al., 1994). Plant-derived cellulose contains both hemicellulose and lignin but cellulose produced by bacteria, also called bacterial cellulose (BC), is the pure form of cellulose. Although the chemical structure of BC is the same as that of plant cellulose, it possesses different physical and chemical properties. For example, the fiber diameter of BC is about one hundredth that of plant cellulose while its Young's modulus is almost equivalent to that of aluminum (Khan et al., 2007). Due to its purity and unusual physico-chemical properties, a wide range of specialty applications of BC can be envisaged in the food and medical field, while it could be used in bulk in the paper and textile industries. However, the current price of BC remains too high to make it commercially attractive.

26.2

Historical overview

In 1886, Brown discovered that Bacterium aceti (now known as Acetobacter xylinum or Gluconoacetobacter xylinum) produces a tough gelatinous film of pure cellulose. This bacterium was then known as `the vinegar plant' because it was the major source of acetic acid. BC attracted more attention in the midtwentieth century. In 1954, Hestrin and Schramm reported the production of microbial cellulose in a glucose-rich medium using the bacterium A. xylinum. Next, Colvin (1957) detected cellulose synthesis in samples containing cell-free extract of A. xylinum, glucose, and adenosine triphosphate (ATP). Schramm and Hestrin (1954) also reported the occurrence of non-cellulose producing (cellulose-negative) mutants of A. xylium. When cellulose-producing strains were grown and transferred repeatedly in a shaken culture, spontaneously forming cellulose-negative (Celÿ) mutants accumulated, causing the lower production yield of BC. Further, Steel and Walker (1957) found that isolates incapable of forming cellulose were present when A. xylinum was grown under agitated and aerated conditions. Coucheron (1991) noted that the insertion sequence element of genes was associated with the inactivation of cellulose production by an A. xylinum strain. The cellulose deficiency in mutants might be due to insertions (i) in the region of the operon outside the 9.9 kb HindIII fragment, (ii) in genes representing known functions in the production of cellulose but which are not part of the cellulose synthase operon, or (iii) in genes whose role in this formation has not yet been identified. For large-scale production of BC, isolation of a strain and finding culture conditions suitable for producing BC in a shear stress field are required. In 1995, Bio Polymer Research (BPR) Co. Ltd. isolated a high cellulose producing strain, A. xylinum subsp. sucrofermentans BPR2001 from agitated culture (Toyosaki et al., 1995) and also isolated sulfaguanidine-resistant

726


mutants, BPR3001E, from BPR2001 (Ishikawa et al., 1995). Cellulose production by BPR3001E was 40% higher than that by BPR2001. More recently, it was found that the cellular activity of cellulose production can be preserved without the spontaneous occurrence of Celÿ mutants in consecutive shake-cultures using a medium containing ethanol (Park et al., 2003a,b). It is generally known that the shear stress generated in shaking cultivation causes the Acetobacter strains to be converted into Celÿ mutants. Since 1996, the effects of the tricarboxylic acid (TCA) cycle related organic acid on BC production has been reported (Matsuoka et al., 1996; Naritomi et al., 1998; Premjet et al., 1999). Supplementing organic acid such as pyruvate, succinate, acetate and lactate to the medium increase the BC yield. BC was produced by A. xylinum BPR2001 in a 50 liter air-lift reactor, whose power consumption is significantly lower than that of the stirred tank reactor, using fructose as the main carbon source (Chao et al., 1997). At present, this 50 liter air-lift reactor is the largest-scale BC production system.

26.3

Biosynthesis

The biosynthesis of BC is a precisely and specifically regulated multi-step process, involving a large number of both individual enzymes and complexes of catalytic and regulatory proteins, whose supramolecular structure has not yet been well defined. The process includes the synthesis of uridine diphosphoglucose (UDPGlc), which is the cellulose precursor, followed by glucose polymerization into the -1,4-glucan chain, and nascent chain association into characteristic ribbon-like structure, formed by hundreds or even thousands of individual cellulose chains. 26.3.1 Biosynthetic pathway As known from the literature (Yoshinaga et al., 1997; De Wulf et al., 1996), the cellulose formation includes five fundamental enzyme mediated steps: the transformation of glucose to UDP-glucose via glucose-6-phosphate and glucose1-phosphate, and finally the addition of UDP-glucose to the end of a growing polymer chain by cellulose synthase. Cellulose synthase (UDP-glucose: 1,4- -Dglycosyltransferase; EC 2.4.1.12) is regarded as the essential enzyme in the synthesis process. It is subjected to a complicated regulation mechanism, which controls activation and inactivation of the enzyme (Vandamme et al., 1998). The cellulose synthase from A. xylinum is subjected to a complex form of regulatory control which has not been encountered previously in a living system. The basis of this regulation appears to lie in the intracellular concentration of an unusual cyclic guanyl nucleotide dimer (originally isolated as an incubation product of guanosine triphosphate (GTP) with cell extracts) (Ross et al., 1985, 1986), which functions as an allosteric effector of enzyme activity. In vitro, cellulose synthase activity displays nearly absolute dependence on the presence

Bacterial cellulose

727

of nanomolar concentrations of this compound, which was identified (Ross et al., 1987) as cyclic bis(30 !50 )-diguanylic acid(c-di-GMP or cGpGp). Currently, it is unknown whether c-di-GMP affects other cellular processes in addition to cellulose synthesis. The pathways of synthesis and degradation of c-di-GMP are catalyzed by enzymes which occur in both soluble and membrane-associated form in cell-free extracts. The formation of the nucleotide activator is attributed to diguanylate cyclase, a predominantly soluble enzyme, which condenses two molecules of GTP in a two-step reaction, via the intermediate linear triphosphate pppGpG. A membrane-bound phosphodiesterase, termed PDE-A, degrades the activator, cleaving a single phosphodiester bond in the cyclic structure to form the linear 50 -phosphoryl dimer pGpG (Ross et al., 1987; Mayer, 1987). This initial degradation product, which is devoid of stimulatory effect, is then further hydrolyzed to yield two molecules of 50 -GMP in a reaction attributed to a second phosphodiesterase, termed PDE-B. This latter phosphodiesterase has been deemed distinct from PDE-A on the basis that the ratio of PDE-A to PDEB activity in membrane preparations is approximately 10:1, whereas in soluble extracts this ratio is reversed (Mayer, 1987). Furthermore, in contrast to the PDE-B reaction, PDE-A activity is inhibited at low concentrations of Ca2+ ions, suggesting that this phosphodiesterase serves as an additional locus of regulatory control, maintained by this cation. A regulation model of cellulose synthesis in A. xylinum was proposed by Ross et al. (1987). 26.3.2 Biosynthetic mechanism Electron microscopy studies have demonstrated that cellulose-synthesizing complex or terminal complex (TC) is linearly arranged in the longitudinal axis of the bacterial rods, and in association with pores at the surface of the bacterium (Zaar, 1979). The diameter of pore in the middle of each TC probably corresponds with that of the cellulose molecule. In the first step of cellulose formation glucan chain aggregates consisting of approximately 6±8 glucan chains are elongated from the TC which is located between the outer and the cytoplasma membrane. These sub-elementary fibrils are assembled in the second step to form microfibrils followed by their tight

Fig. 26.1

Generalized model of ribbon assembly in A. xylinum (Brown, 1992).

728


assembly to form a ribbon as the third step (Fig. 26.1). The matrix of interwoven ribbons constitutes the BC membrane or pellicle (Brown, 1992). The ribbon consists of approximately 46 microfibrils which average 1:6 5:8 nm in cross section and elongates at a rate of 2 m/min (Brown et al., 1976).

26.4

Manufacture

Cellulose-producing bacteria include members of the genera Acetobacter, Rhizobium, Agrobacterium, and Sarcina (Jonas and Farah, 1998). Acetobacter xylinum is the most efficient synthesizer of bacterial cellulose and thus has been applied as a model microorganism for basic and applied studies on bacterial cellulose (Cannon and Anderson, 1991). The production of bacterial cellulose could be carried out in either solid-phase cultivation or submerged culture (ElSaied et al., 2004). Two methods are generally employed for the production of bacterial cellulose; namely stationary culture and agitated culture (Watanabe et al., 1998). In the static cultivation, the bacterial cellulose is produced as a gelatinous membrane on the surface of the medium, while in the agitated culture, the bacterial cellulose is accumulated in dispersed suspension as irregular masses, such as granule, stellate, and fibrous strand. The agitated culture method is mainly applied for industrial production of bacterial cellulose (El-Saied et al., 2004), although most of the biomedical and cosmoceutical applications require bacterial cellulose to be in a proper shape (e.g., film, membrane or sheet), which is produced in static cultivation mode. Until now, the stationary culture conditions have been successfully reported, however, agitated culture for the production of bacterial cellulose faces many problems, including genetic instability of the producer organism and their subsequent conversion to cellulose non-producing mutants, non-Newtonian behavior during mixing of bacterial cellulose, or proper oxygen supply (Czaja et al., 2004). These problems associated with agitated cultures have been thoroughly investigated with some degree of success. For example, Park et al. (2003a,b) reported the possibility to preserve the cellulose production ability of the cells without the spontaneous occurrence of cellulose non-producing mutants. Whatever the cultivation mode for the production of bacterial cellulose, the main carbon source by Acetobacter or Gluconacetobacter xylinus is glucose or sucrose because the precursor in cellulose synthesis is uridine diphosphoglucose. The biosynthesis of cellulose from other carbon sources, such as 5- or 6-carbon monosaccharides, oligossaccharides, starch, alcohol, and organic acid has also been reported. Moreover, fructose and glycerol are also used as carbon sources and these result in almost similar yields of bacterial cellulose as that that from glucose while galactose and xylose yields are smaller. The bacterial cellulose yield from sucrose is half the yield from glucose. The use of D-arabitol as a carbon source results in six times as much cellulose as that from D-glucose. A specific complex nitrogen source is also required for the cellulose-producing

Bacterial cellulose

729

strain. Most of the media used for the production of bacterial cellulose utilizes yeast extract and peptone as the nitrogen sources. A few amino acids, e.g., methionine and glutamate, have also been recommended for this purpose. The vitamins pyridoxine, nicotinic acid, p-aminobenzoic acid, and biotin stimulate cell growth and cellulose production (El-Saied et al., 2004). The cell growth and cellulose production is significantly affected by the pH of the culture broth and therefore, pH control around an optimum value is desirable. The conversion of glucose to gluconic acid leads to a significant drop in pH of the medium in the batch culture. The optimal pH range for cellulose production by A. xylinum is 4±6 while some other researchers (Oikawa et al., 1995; Delmer and Amor, 1995) demonstrated pH 4±7 as optimum. In addition to the pH of the nutrient broth, the yield of bacterial cellulose is also temperature dependent. The optimal growth temperature for cellulose production is 25± 30 ëC. The cellulose synthesis occurs at the air/cellulose pellicle interface, and thus oxygen is an important factor for cellulose production. The production rate and the yield of bacterial cellulose are proportional to the oxygen transfer rate (OTR) and oxygen transfer coefficient (KLa). Excessive oxygen supply is reported to result in a decrease in bacterial cellulose productivity due to a loss of substrate by direct oxygen (El-Saied et al., 2004). After fermentation, the bacterial cellulose is generally harvested from the culture medium by centrifugation or filtration followed by washing with distilled water and re-centrifugation or filtration. The microbial cells are removed from the bacterial cellulose by destroying them during a hot caustic treatment. The suspension is then filtered and the filter cake is washed thoroughly with distilled water in order to remove the traces of sodium hydroxide. The bacterial cellulose is finally freeze-dried.

26.5

Structure

Cellulose is an unbranched polymer of -1!4-linked glucopyranose residues. The chemical structure of plant and bacterial cellulose is the same except the degree of polymerization, which is about 13,000 to 14,000 for plant and 2,000 to 6,000 for bacterial cellulose (Jonas and Farah, 1998). Moreover, the macromolecular structure and properties of bacterial cellulose also differ from the latter (Bielecki et al., 2002). During biosynthesis, the bacteria utilize various carbon compounds of the nutrition medium which are then polymerized into single, linear -1,4-glucan chains and finally secreted outside the cells through a linear row of pores located on their outer membrane. The subsequent assembly of the -1,4-glucan chains outside the cell leads to the formation of subfibrils (consisting of 10±15 nascent -1,4-glucan chains). The subfibril having a width of approximately 1.5 nm is one of the thinnest naturally occurring fibers. These subfibrils are crystallized into microfibrils, in turn into bundles, and the latter into ribbons. The ribbon is composed of about 1000 individual glucan chains (Bielecki et al., 2002). This

730


series of processes results in the formation of a thick, gelatinous membrane in static culture conditions. The 3D structure of such a membrane consists of an ultrafine network of cellulose nanofibres (3±8 nm) which are highly uniaxially oriented. This type of 3D structure results in a higher crystallinity (60±80%) of bacterial cellulose and tremendous mechanical strength. Vascular plant cellulose, however, lacks such a 3D structure (Bielecki et al., 2002). Native bacterial cellulose occurs in two different crystalline structures, namely cellulose I and cellulose I (Yoshinaga et al., 1997). A triclinic unit cell consisting of one cellulose chain for cellulose I and a monoclinic unit cell consisting of two cellulose chains for cellulose I . These two types of crystalline structures appear to be separately distributed in the microfibril of cellulose with exception of tunicin (sea squirt cellulose) which is pure cellulose I . Cellulose I is dominant in bacterial cellulose while cellulose I is dominated in plant cellulose (Sugiyama et al., 1991).

26.6

Functional properties

Bacterial cellulose has the same chemical structure as that of plant cellulose, yet it possesses different physical and chemical properties. The characteristic physical properties of bacterial cellulose are summarized in Table 26.1 and are discussed as follows. 26.6.1 Macromolecular structure As mentioned earlier, the macromolecular structure and properties of bacterial cellulose differ from those of the plant cellulose. Bacterial cellulose is composed of unique ribbon-shaped fibrils (El-Saied et al., 2004). The width of the fibril is approximately 1.5 nm and belong to the thinnest naturally occurring fibers. It is worth noting that the fiber diameter of bacterial cellulose is about one hundredth that of plant cellulose (Khan et al., 2007). The ribbons are made up from several Ê 2 in smaller microfibrils. Iguchi et al. (2000) stated that these were 20±40 A Ê 2, diameter, Brown et al. (1976) stated that the cross-sections averaged 16 58 A with ~46 microfibrils making up a ribbon, and Fink et al. (1997) found evidence Ê 2. for crystallite dimensions of 130 70 A 26.6.2 Crystallinity and degree of polymerization Bacterial cellulose is also distinguished from its plant counterpart by a high crystallinity index (above 60%). The native bacterial cellulose exist in two different crystalline structures, i.e., cellulose I and cellulose I (Yoshinaga et al., 1997). The content of cellulose I is approximately 60% in bacterial cellulose while it is only approximately 30% in the higher plant cellulose, cotton and ramie. In contrast, cellulose I is the major component in plant cellulose (Sugiyama et al., 1991). Crystallinity is considered to be a key determinant of the properties of cellulose.

Bacterial cellulose Table 26.1

731

Functional properties of bacterial cellulose

Property

Description

Purity

Chemically pure form of cellulose and is free from hemicelluloses, lignin and pectin Biodegradable, recyclable and renewable High tensile strength, consistent dimensional strength, light weight and durable Remarkable high water-holding capacity, selective porosity, high mechanical strength in wet state, high surface-to-volume carrier capacity Bacterial cellulose has dynamic capabilities of fiber forming Uniaxially strengthened membranes can be produced Direct assembly of extremely thin, submicron, optical clear membrane during biosynthesis and thus avoiding the need for the intermediate of paper or textile formation from pulp Bacterial cellulose has a very high moldability and can be produced in the form of a gelatinous membrane which can be molded into any shape and size during its synthesis The crystallization of bacterial cellulose can be delayed by introduction of dyes into culture medium. The physical properties such as molecular weight and crystallinity can be controlled during biosynthesis Various cellulose derivatives (such as cellulose acetate, carboxymethylcellulose, methyl cellulose, etc.) can be directly synthesized. The desired cellulose crystalline allomorph (cellulose I or cellulose II) can be directly controlled

Biodegradability Mechanical strength Water-holding capacity Cellulose orientation Direct membrane formation Moldability

Direct modification

Direct synthesis of cellulose product

Moreover, the degree of polymerization (DP) of cellulose from both these natural sources is also different from each other. The degree of polymerization of bacterial cellulose is usually between 2,000 and 6,000 (Jonas and Farah, 1998) but, in some cases, reaching even 16,000 or 20,000 (El-Saied et al., 2004). On the other hand the average degree of polymerization of plant cellulose varies from 13,000 to 14,000 (Teeri, 1997). The structural features of bacterial cellulose vary according to culture conditions in which it has been produced and the strain used. The crystallinity and cellulose I content of cellulose are lower in an agitated culture than that in a static culture. Similarly, the degree of polymerization of cellulose molecule is also lower in agitated culture conditions (El-Saied et al., 2004). 26.6.3 Mechanical strength It has been reported that the dried sheet of purified gelatinous membrane of bacterial cellulose has extremely high Young's modulus, of more than 15 GPa. This value is the highest of planar-oriented sheets or non-oriented sheets made

732


Table 26.2 Mechanical properties of bacterial cellulose and other organic layer materials (adapted from Klemm et al., 2005) Material Bacterial cellulose Polypropylene Polyethylene terephthalate Celluphane

Young's modulus (GPa)

Tensile strength (MPa)

Elongation (%)

15±35 1.0±1.5 3±4 2±3

200±300 30±40 50±70 20±100

1.5±2.0 100±600 50±300 15±40

from various organic polymers, which have a Young's modulus of less than 5 GPa. Furthermore, the specific Young's modulus, which is the quotient of Young's modulus by density, corresponds to that of aluminum. This high Young's modulus of the sheet may be due to the strong interfibril binding of the ultrafine fibrils of the bacterial cellulose and may be dependent on the crystallinity of the bacterial cellulose. The sheet prepared from the bacterial cellulose produced in an agitated culture has a slightly lower Young's modulus than that of statically-produced bacterial cellulose. This is because the cellulose produced with agitation has a substantially disordered structure compared with that in static culture (Yoshinaga et al., 1997). Nishi et al. (1990) reported a tremendously high Young's modulus which was close to 30 GPa, for sheets obtained from BC pellicles when adequately processed. Table 26.2 describes the mechanical properties of bacterial cellulose and other organic layer materials (Klemm et al., 2005). Due to this remarkable modulus, bacterial cellulose sheets seem to be an ideal candidate as raw material to further enhance the Young's modulus of high-strength composites. 26.6.4 Water-holding capacity Bacterial cellulose is water-insoluble and due to its large network of fibers it has a very large surface area. These fibers have approximately 200 times the surface area of fibers from plant cellulose. Due to the unique nano-morphology coupled with its ability to form hydrogen bonds which accounts for their unique interactions with water, bacterial cellulose can absorb up to 200 times of its dry mass of water. When bacterial cellulose is used in suspension, it exhibits pseudoplastic thickening properties. Moreover, bacterial cellulose displays great elasticity, high wet strength, and conformability (Czaja et al., 2006; US Congress, 1993). The small size of bacterial cellulose fibrils and thus the high water-holding capacity seems to be a key factor that determines its remarkable performance as a wound-healing system. Furthermore, the never dried cellulose membrane is a highly nano-porous material that allows for the potential transfer of antibiotics or other medicines into the wound, while at the same time serving as an efficient physical barrier against any external infection (Czaja et al., 2006).

Bacterial cellulose

733

26.6.5 Miscellaneous properties Bacterial cellulose has a very high moldability. It can be produced in the form of a gelatinous membrane which can be molded into any shape and size during its synthesis, depending on the fermentation technique and conditions used (Czaja et al., 2006). The BC is the chemically pure form of cellulose and is free from hemicellulose, pectin, and lignin that are associated with plant cellulose and are difficult to eliminate (Khan et al., 2007). A vigorous treatment with strong bases at high temperatures allows the removal of cells embedded in the cellulose net, and it is possible to achieve a non-pyrogenic, non-toxic, and fully biocompatible biomaterial (Czaja et al., 2006). The various desired properties of bacterial cellulose can be directly controlled during biosynthesis. For example, the crystallization of bacterial cellulose can be delayed by introduction of dyes into culture medium. The physical properties such as molecular weight and crystallinity can be controlled during biosynthesis. Moreover, various derivatives of cellulose (such as cellulose acetate, carboxymethylcellulose, methyl cellulose, etc.) can be directly synthesized during production of bacterial cellulose. The desired cellulose crystalline allomorph (cellulose I or cellulose II) can also be directly controlled (El-Saied et al., 2004).

26.7


Bacterial cellulose is a new functional material for a wide range of applications even in those areas where the use of plant cellulose is limited. This may be largely attributed to a high purity with a crystallinity structure and high water absorption capacity and mechanical strength in the wet state. The major current and potential applications of bacterial cellulose can be summarized as follows. 26.7.1 Food applications Bacterial cellulose has important applications in a variety of food formulations due of its unique properties and structure. Its use is particularly recommended in situations where low use levels, lack of flavor interactions, foam stabilization, and stability over wide pH range, temperature, and freeze-thaw conditions are required. Potential uses include pourable and spoonable dressings, sauces, and gravies; frostings and icings; sour cream and cultured dairy products; whipped toppings and aerated desserts, and frozen dairy products. The use of bacterial cellulose in combination with other agents such as sucrose and carboxymethylcellulose improves the dispersion of the product. It is also a low-calorie additive, thickener, stabilizer, texture modifier, and can be used in pasty condiments and in ice cream (Khan et al., 2007). Nata de Coco, produced by G. xylinus using coconut milk as the carbon source, is a popular food or dessert in the Philippines. It is also imported into Japan. Nata de Coco has the plasma cholesterol-lowering effect and is believed to protect against bowel cancer, artheriosclerosis, and coronary thrombosis, and prevents a sudden rise of glucose in the urine. Chinese Kombucha or Manchurian

734


Tea, obtained by growing yeast and Acetobacter in a medium containing tea extract and sugar, is also a popular bacterial cellulose containing food product. Kombucha is believed to protect against certain cancers (El-Saied et al., 2004). 26.7.2 Applications in paper and paper products Bacterial cellulose is composed of very small clusters of cellulose microfibrils. Therefore, it increases tremendously the strength and durability of pulp when included into paper. The Ajinomoto Co. and Mitsubishi Paper Mills in Japan are currently producing bacterial cellulose for paper products. The disintegrated bacterial cellulose functions as a high retention aid for paper making. Bacterial cellulose is also a valuable component of synthetic paper since nonpolar polypropylene and polyethylene fibers, providing insulation, heat resistance, and fire-retarding properties, cannot form hydrogen bonds. The amount of wood pulp in this type of paper is usually from 20 to 50% to achieve good quality (ElSaied et al., 2004). Recently, several efforts have been directed towards making electronic paper which consists of bacterial cellulose with an electronic dye between transparent electrodes. The device at first looks like fine white paper but when a voltage is applied, the dye turns dark and remains dark, even when the power is turned off. When an opposite voltage is applied, the dye lightens and the device again appears paper-white. This technology could be a basis for electronic books, wallpaper that changes patterns, flexible electronic newspapers, and dynamic paper (Shah and Brown, 2005). 26.7.3 Development of audio components The development of an acoustic transducer (audio speaker diaphragms) by Sony Corporation and Ajinomoto from bacterial cellulose was the first example of the commercial applications of this valuable product. This application exploits the mechanical properties, especially the higher Young's modulus, of bacterial cellulose. A high sonic velocity and high internal loss is required for an acoustic transducer. The sonic velocity is equal to the square root of the specific Young's modulus, which is equivalent to the quotient of Young's modulus by density. The sonic velocity for bacterial cellulose sheet is approximately 5000 m/sec due to an extremely high Young's modulus and substantially low density. The bacterial cellulose sheet has a high internal loss of 0.03 despite its high sonic velocity. These properties make the bacterial cellulose an ideal material for such diaphragms. The bacterial cellulose is already used extensively for the production of various types of speakers units and headsets (Yoshinaga et al., 1997; El-Saied et al., 2004). 26.7.4 Biomedical applications Bacterial cellulose is a very versatile material that finds a wide array of biomedical applications, from topical wound dressings to the durable scaffolds required for tissue engineering.

Bacterial cellulose

735

The Johnson & Johnson Company initiated efforts in the early 1980s to commercialize the application of bacterial cellulose in the treatment of different wounds. A Brazilian company, BioFill Produtos Bioetecnologicos (Curitiba, PR Brazil) developed a new wound healing system based on bacterial cellulose. The various products from this company includes Biofills and Bioprocesss (used in the treatment of burns, and ulcer therapy as temporary artificial skin), and Gengiflexs (applied in treatment of periodontal diseases). These products differ from each other with regard to the variable initial concentrations of carbon sources, surface/volume ratios, and extended times of fermentation. Biofills is produced within 2 days, whereas Gengiflexs takes 8 days of fermentation. A gelatinous membrane of bacterial cellulose was commercialized in Brazil as an artificial skin (wound dressing) which was superior to conventional gauze due to a high mechanical strength in the wet state, substantial permeability for liquids and gases, and low irritation of skin. A US-based corporation, Xylos, introduced the XCells family of wound care products which includes XCells Cellulose Wound Dressing and XCells Antimicrobial Wound Dressing. These products have been marketed in the US since 2003. Another bacterial cellulose preparation, Prima Cel, from Xylos Corp. has been applied as a wound dressing in clinical tests to heal ulcers (El-Saied et al., 2004; Czaja et al., 2006, 2007; Klemm et al., 2005). It has been demonstrated that bacterial cellulose can be suitably shaped for application during biosynthesis. Bacterial cellulose can be synthesized in the shape of formed hollow bodies directly in the culture medium without subsequent treatment. The hollow fibers (bacterial synthesized cellulose (BASYC) tubes) can be used as artificial blood vessels and ureters. Bacterial cellulose is used to protect immobilized glucose analyzers in biosensors for assays of glucose levels due to its high tensile strength, durability, and permeability to liquid and gases. This bacterial cellulose membrane introduced the electrode stability. Cellulose gels containing immobilized animal cell were used for the synthesis of interferon, interleukin-1, cytostatic, and monoclonal antibodies (Klemm et al., 2001, 2005; El-Saied et al., 2004; Czaja et al., 2006, 2007). BC has potential to be used as a substrate for tissue engineering of cartilage due to its high strength in the wet state as well as its moldability in situ, biocompatibility and relatively simple, cost-efficient production (Svensson et al., 2005). Moreover, bacterial cellulose was successfully used in experiments on dogs as a substitute for the duramater in the brain (El-Saied et al., 2004). Bacterial cellulose has potential to be used for veterinary and cosmetic applications (Klemm et al., 2005). 26.7.5 Other applications of bacterial cellulose Weyerhaeuser Co. (Tacoma, Washington, USA) and Cetus Co. (Emeryville, California, USA) has developed a bacterial cellulose product `Cellulon', a bulking agent with a broad spectrum of applications, e.g., in the mining sector, in binding and coating applications. Bacterial cellulose can also be applied as a

736


carrier for immobilization of biocatalysts. It can also be used as a raw material for preparation of cellulose derivatives, e.g., CMC, hydroxymethyl cellulose, cellulose acetate, and methyl cellulose. Bacterial cellulose is also a good binder in nonwoven fabric-like products which is applied in surgical drapes and gowns, and containing various hydrophilic and hydrophobic, natural, and synthetic fibers, such as cellulose esters, polyolefin, nylon, acrylic glass, or metal fibers. The tensile and tear strength of the fabric can be improved by incorporation of a small amount of bacterial cellulose, e.g., 10% of the bacterial polymer is equivalent to 20±30% of latex binder (El-Saied et al., 2004). Philip Morris Inc. developed a paper wrapper for tobacco using bacterial cellulose while The Goodyear Tire and Rubber Co. achieved reinforcement of tire by application of bacterial cellulose (Baldwin et al., 1993; Tung et al., 1994).

26.8

Regulatory status

Bacterial cellulose has been determined to be `generally recognized as safe' (GRAS) as a food ingredient through the self-determination process under 21 CFR 182.1 using scientific procedures in accordance with 201 (s) (21 USC Section 321 (s)) of the Federal Food, Drug and Cosmetic Act. A GRAS affirmation petition was filed on the basis of the GRAS determination of bacterial cellulose on December 11, 1991, which was accepted by the Food and Drug Administration (FDA) for filing on April 13, 1992. Amendment of the GRAS affirmation petition to GRAS notification was requested under the Interim Policy provision of the FDA's April 17, 1997, GRAS notification proposal (Sec. 21 CFR 170.36 (g) 2) (Omoto et al., 2000).

26.9

References and further reading

(1993), `Smoking article wrapper for controlling burn rate and method for making same', US patent 5,263,999. BIELECKI S, KRYSTYNOWICZ A, TURKIEWICZ M, KALINOWSKA H (2002), `Bacterial cellulose', in Vandamme E J, De Baets S, Steinbuechel A, eds, Biopolymers, Wiley-VCH, Weinheim. BROWN A J (1886), Àn acetic acid ferment which forms cellulose', J Chem Soc, 49, 432± 439. BROWN JR R M (1992), Èmerging technologies and future prospects for industrialization of microbially derived celluose', in Ladisch M R and Bose A, eds, Harnessing Biotechnology for the 21st Century, Washington DC, American Chemical Society, 76±79. BROWN JR R M, WILLISON J H M, RICHARDSON C L (1976), `Cellulose biosynthesis in Acetobacter xylinum: visualization of the site of synthesis and direct measurement of the in vivo process', Proc Nati Acad Sci USA, 73, 4565±4569. CANNON R E, ANDERSON S M (1991), `Biogenesis of bacterial cellulose', Crit Rev BALDWIN S D, GAUTAM N, HOUGHTON K S, ROGERS R M, RYDER J L

Bacterial cellulose Microbiol, 17, 435±447.

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(1997), `Production of bacterial cellulose by Acetobacter xylinum with an air-lift reactor', Biotechnol Tech, 11, 829±832. COLVIN J R (1957), `Formation of cellulose microfibrils in a homogenate of Acetobacter xylinum', Arch Biochem Biophys, 70, 294±295. COUCHERON D H (1991), Àn Acetobacter xylinum insertion sequence element associated with inactivation of cellulose production', J Bacteriol, 173, 5723±5731. CZAJA W, ROMANOVICZ D, BROWN R M JR (2004), `Structural investigations of microbial cellulose produced in stationary and agitated culture', Cellulose, 11, 403±411. CZAJA W, KRYSTYNOWICZ A, BIELECKI S, BROWN R M JR (2006), `Microbial cellulose ± the natural power to heal wounds', Biomaterials, 27, 145±151. CZAJA W K, YOUNG D J, KAWECKI M, BROWN R M JR (2007), `The future prospects of microbial cellulose in biomedical applications', Biomacromolecules, 8, 1±12. DELMER D P (1999), `Cellulose biosynthesis: exciting times for a difficult field of study', Annu Rev Plant Physiol Plant Mol Biol, 50, 245±276. DELMER D P, AMOR Y (1995), `Cellulose biosynthesis', Plant Cell, 7, 987±1000. DE WULF P, JORIS K, VANDAMME E J (1996), Ìmproved cellulose formation by an Acetobacter xylinum mutant limited in (keto)gluconate synthesis', J Chem Technol Biotechnol, 67, 376±380. EL-SAIED H, BASTA A H, GOBRAN R H (2004), `Research progress in friendly environmental technology for the production of cellulose products (bacterial cellulose and its application)', Polym-Plast Technol Eng, 43, 797±820. EMBUSCADO M E, MARKS J S, BEMILLER J N (1994), `Bacterial cellulose. Optimization of cellulose production by Acetobacter xylinum through response surface methodology', Food Hydrocoll, 8, 419±430. FINK H P, PURZ H J, BOHN A, KUNZE J (1997), Ìnvestigation of the supramolecular structure of never dried bacterial cellulose', Macromol Symp, 120, 207±217. HESTRIN S, SCHRAMM M (1954), `Synthesis of cellulose by Acetobacter xylinum: preparation of freeze dried cells capable of polymerizing glucose to cellulose', Biochem J, 58, 345±352. IGUCHI M, YAMANAKA S, BUDHIONO A (2000), `Morphology and fracture behavior in aliphatic polyketones', J Mater Sci, 35, 271±277. ISHIKAWA A, MATSUOKA M, TSUCHIDA T, YOSHINAGA F (1995), Increase in cellulose production by sulfaguanidine-resistant mutants derived from Acetobacter xylinum subsp. sucrofermentans, Biosci Biotech Biochem, 59, 2259±2262. JONAS R, FARAH L F (1998), `Production and application of microbial cellulose', Polym Degrad Stab, 59, 101±106. KHAN T, PARK J K, KWON J-H (2007), `Functional biopolymers produced by biochemical technology considering applications in food engineering', Korean J Chem Eng, 24 (5), 816±826. KLEMM D, SCHUMANN D, UDHARD U, MARSCH S (2001), `Bacterial synthesized cellulose ± artficial blood vessels for microsurgery', Prog Polym Sci, 26, 1561±1603. KLEMM D, HEUBLEIN B, FINK H-P, BOHN A (2005), `Cellulose: fascinating biopolymer and sustainable raw material', Angew Chem Int Ed, 44, 3358±3393. MATSUOKA M, TSUCHIDA T, MATSUSHITA K, ADACHI O, YOSHINAGA F (1996), À synthetic medium for bacterial cellulose production by Acetobacter xylinum subsp. sucrofermentans', Biosci Biotech Biochem, 60, 575±579. MAYER R (1987), `Characterization of thy Phosphodiesterases Acting on c-di-GMP' in CHAO Y P, SUGANO Y, KOUDA T, YOSHINAGA F, SHODA M

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Acetobucter xylinum', MSc thesis, The Hebrew University of Jerusalem, Jerusalem, Israel. NARITOMI T, KOUDA T, YANO H, YOSHINAGA F (1998), Èffect of lactate on bacterial cellulose production from fructose in continuous culture', J Ferment Bioeng, 85, 89±95. NISHI Y, URYU M, YAMANAKA S, WATANABE K, KITAMURA N, IGUCHI M, MITSUHASHI S (1990), `The structure and mechanical properties of sheets prepared from bacterial cellulose. Part 2: Improvement of the mechanical properties of sheets and their applicability to diaphragms of electro-acoustic transducers', J Mater Sci, 25, 2997± 3001. OIKAWA T, MORINO T, AMEYAMA M (1995), `Production of cellulose from D-arabitol by Acetobacter xylinum KU-1', Biosci Biotech Biochem, 59, 1564±1565. OMOTO T, UNO Y, ASAI I (2000), `Bacterial cellulose', in Phillips G O, Williams P A, eds, Handbook of Hydrocolloids, Woodhead Publishing Limited, Cambridge. PARK J K, PARK Y H, JUNG J Y (2003a), `Production of bacterial cellulose by Gluconacetobacter hansenii PJK isolated from rotten apple', Biotechnol Bioprocess Eng, 8, 83±88. PARK J K, JUNG J Y, PARK Y H (2003b), `Cellulose production by Gluconacetobacter hansenii in a medium containing ethanol', Biotechnol Lett, 25, 2055±2059. PREMJET, S, SHIMAMOTO A, OHTANY Y, SAMESHIMA K (1999), `The importance of TCA cycle related acids in bacterial cellulose production', Fiber, 55, 48±53. ROSS P, ALONI Y, WEINHOUSE H, MICHAELI D, WEINBERGER-OHANA P, MAYER R, BENZIMAN M

(1985), Àn unusual guanyl oligonucleotide regulates cellulose synthesis in Acetobacter xylinum', FEBS Mt, 186, 191±196.

ROSS P, ALONI Y, WEINHOUSE H, MICHAELI D, WEINBERGER-OHANA P, MAYER R, BENZIMAN M

(1986), `Control of cellulose synthesis in A. xylinum. A unique guanyl oligonucleotide is the immediate activator of cellulose synthase', Carbohydr Res, 149, 101±117.

ROSS P, WEINHOUSE H, ALONI Y, MICHAELI D, WEINBERGER-OHANA P, MAYER R, BRAUN S, DE

VROOM E, VAN DER MAREL G A, BANBOOM J H, BENZIMAN M (1987), `Regulation of cellulose synthesis in Acetobacter xylinum by cyclic diguanylic acid', Nature, 325, 279±281. SCHRAMM M, HESTRIN S (1954), `Factors affecting production of cellulose at the air/liquid interface of a culture of Acetobacter xylinum', J Gen Microbiol, 11, 123±129. SHAH J, BROWN R M JR (2005), `Towards electronic paper displays made from microbial cellulose', Appl Microbiol Biotechnol, 66, 352±355. STEEL R, WALKER T K (1957), Celluloseless mutants of certain Acetobacter species, J Gen Microbiol, 17, 12±18. SUGIYAMA J, VUONG R, CHANZY H (1991), Èlectron diffraction study on the two crystalline phases occurring in native cellulose from an algal cell wall', Macromolecules, 24, 4168±4175. SVENSSON A, NICKLASSON E, HARRAH T, PANILAITIS B, KAPLAN D L, BRITTBERG M, GATENHOLM P (2005), `Bacterial cellulose as a potential scaffold for tissue engineering of cartilage', Biomaterials, 26,, 419±431. TEERI T T (1997), `Crystalline cellulose degradation: new insight into the function of cellobiohydrolases', Tibtech, 15, 160±167. TOYOSAKI H, NARITOMI T, SETO A, MATSUOKA M, TSUCHIDA T, YOSHINAGA F (1995), `Screening of bacterial cellulose-producing Acetobacter strains suitable for agitated culture', Biosci Biotech Biochem, 59, 1498±1502.

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(1994), `Reticulated bacterial cellulose reinforcement for elastomers', US patent 5,290,830. US CONGRESS, OFFICE OF TECHNOLOGY ASSESSMENT (1993), Biopolymers: Making Materials Nature's Way ± Background Paper, OTA-BP-E-102, Washington, September. VANDAMME E J, DE BAETS S, VANBAELEN A, JORIS K, DE WULF P (1998), Ìmproved production of bacterial cellulose and its application potential', Polym Degrad Stab, 59, 93±99. WATANABE K, TABUCHI M, MORINAGA Y, YOSHINAGA F (1998), `Structural features and properties of bacterial cellulose produced in agitated culture', Cellulose, 5, 187± 200. YAMANAKA S, WATANABE K (1994), Àpplication of bacterial cellulose', in Gilbert R D, ed., Cellulose Polymers, Blends and Composites, MuÈnchen, Hansen Verlag, 207± 215. YOSHINAGA F, TONOUCHI N, WATANABE K (1997), `Research progress in production of bacterial cellulose by aeration and agitation culture and its application as a new industrial material', Biosci Biotech Biochem, 61, 219±224. ZAAR K (1979), `Visualization of pores (export sites) correlated with cellulose production in the envelope of the gram-negative bacterium Acetobacter xylinum', J Cell Biology, 80, 773±777. TUNG W C, TUNG D A, CALLANDER D D, BAUER R G

27 Microcrystalline cellulose G. Krawczyk, A. Venables and D. Tuason, FMC BioPolymer, USA

Abstract: This chapter describes the technology and functional properties of microcrystalline cellulose (MCC) in food applications. A number of the functional properties comprise texture modification, suspension of solids, heat stability, fat replacement, ice crystal control, bulking agent, emulsion stabilization, and foam stability. New line extensions of colloidal MCC-based products with improved physical properties have been developed to address certain requirements in a range of food systems. Today a variety of MCC products are used extensively for food, pharmaceutical, and industrial applications. Formulations and procedures are included to assist the formulator in addressing their specific needs. Key words: microcrystalline cellulose, AvicelÕ, colloidal, texture, functional properties.

27.1

Introduction

Microcrystalline cellulose (MCC) has been used for over 40 years to provide physical stability and texture modification in a wide variety of food applications. MCC can be used in virtually all food segments such as dairy, convenience, and low moisture applications that require unique stabilization solutions or bulk filler properties to develop stable and palatable products. Properly utilized, MCC can provide heat stability in bakery applications and suspension of insoluble particulates in beverages. Other examples include fat and solids substitution in salad dressings and heat shock stability and texture enhancement in frozen desserts. In addition to stabilization, food scientists encounter other hurdles when creating new products. Generally, stabilizers can have a tendency to disrupt flavor release and interfere with processing efficiencies. Microcrystalline cellulose is known to impart clean flavor without masking desirable flavor

Microcrystalline cellulose

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profiles. Manufacturers also rely on the unique rheological properties of microcrystalline cellulose to assist in processing. The combined attributes of texture modification, physical stability, and processing advantages associated with MCC make it a versatile stabilization ingredient. As food distribution channels become more advanced, new markets emerge, and manufacturers consolidate production facilities, new challenges will be placed on food scientists. As a result, research and development continues in the exploration of new MCC-based products that will expand the spectrum of its functionalities. FMC Corporation is offering newly developed alloys of MCC that will overcome some of the limitations of the more traditional grades of MCC. Several of these newly developed products will be discussed in light of the emerging trends which are driving their development. A detailed description of microcrystalline cellulose and the functional attributes within each food segment will be discussed in detail in this chapter. The organization of information will be based on the physical properties inherent in MCC and on a description of practical applications that utilize those properties. Formulations and procedures will be included to assist the reader in addressing their specific needs.

27.2

Raw materials and manufacturing process

Microcrystalline cellulose (MCC) is a purified form of cellulose, which is the key structuring agent in all plant material. It is the most abundant and naturally occurring polysaccharide found in nature. Cellulose is a polysaccharide of glucose where the recurring unit is actually two consecutive glucose anhydride units (cellobiose). It is of sufficient chain length to be insoluble in water or dilute acids and alkalis at ordinary temperatures.1 The 1,4- -glycosidic linkages of glucose units is responsible for the non-digestive nature of the polymer. The beta linkage also allows an extension of the molecular chain giving rise to tight linear arrangements between individual polymers. Figure 27.1 illustrates the molecular structure of cellulose where the value of n (degree of polymerization) may range from about 50 to 3500 depending on the native source and/or chemical treatments.2 The purification process utilized to manufacture microcrystalline cellulose renders the polymer into a highly functional food ingredient. Highly refined pulpwood is most commonly used as the starting raw material for manufacturing

Fig. 27.1

Molecular structure of cellulose.

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MCC, although cotton linters and various agricultural by-products can also be sourced. The pulping process is utilized to remove lignin, polysaccharides, low molecular weight cellulosic material, and extractives. The product of dissolving grade wood pulp processes is a high molecular weight cellulose fiber (cellulose). These fibers are composed of millions of microfibrils. The individual microfibril is composed of two regions, amorphous and crystalline. Amorphous regions are characterized by the nonlinear arrangement and flexible mass of polymeric linkages. Crystalline regions are composed of tight bundles of cellulose polymers assembled in a rigid and linear arrangement. Crystalline alignments give rise to very powerful associative forces responsible for the great strength of cellulosic materials.2 Strong mineral acid hydrolysis is employed to remove all amorphous cellulose portions of the fiber. The product of hydrolysis is a mass of cellulose crystals processed to a level off degree of polymerization (LODP). Following the steps of neutralization, washing, and filtration, the purified microcrystalline cellulose wetcake is diluted in water, and spray-dried to provide large particulate (non-colloidal) MCC. Non-colloidal MCC products are useful in food as a source of fiber and bulk and may also be used as anti-caking agents for oily substances such as shredded cheese. The wetcake can also be subjected to a wet mechanical disintegration step prior to drying. In this process, MCC particles are separated to submicron size and co-dried with carboxymethylcellulose (CMC) or other functional hydrocolloids, e.g., alginate and pectin. These are often referred to as colloidal grades of microcrystalline cellulose and represent the category of MCC products most commonly used in food applications as stabilizers and texture modifiers. Colloidal MCC products are marketed as dry ingredients that hydrate in the presence of water to form dispersions of insoluble microcrystals capable of providing numerous functional attributes. Properly hydrated sols of MCC form a three-dimensional network based on the electrostatic repulsion of negatively charged cellulose crystals, a charge that is imparted on the surface by the strong association of the functional group inherent in the specific soluble hydrocolloid component. Water management based on this type of network is the basis for all the unique properties imparted to food systems containing microcrystalline cellulose. Colloidal MCC/CMC (AvicelÕ CL-611, RC-591, RC-581, and RC-501) products were historically the first colloidal MCC products that were developed to provide special functional properties for specific end uses.3 These functional properties include ice crystal control, texture modification, emulsion stabilization, heat stability, foam stability, suspension of solids, and fat replacement. More recently, modification of the functional properties of MCC, by novel coprocessing concepts, has resulted in the discovery of several potentially useful MCC alloys, each offering special properties for specific uses. By modifying the degree of the MCC/CMC interaction through special processing techniques, a colloidal MCC/CMC product (AvicelÕ RT 1133), is made which has the ability to meet and exceed the thermal Fo death time requirements of retort sterilization while minimizing total process time. An ultra fine MCC/CMC/CaCO3


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composition, which is an effective suspending agent in calcium fortified milk, has been made by adding CaCO3 during coprocessing. The CaCO3 was effective in further attriting MCC aggregates during the process to prepare ultra fine MCC particles and thus create a uniquely effective colloidal ingredient.4 Another colloidal MCC/CMC product, denoted as Microquick WC-595, had been developed for use in dry mix food systems, where only a minimal amount of shear was available to achieve full dispersion. This readily dispersible ingredient was produced by incorporating dried, sweet dairy whey with the colloidal material prior to spray-drying.5 Besides keeping all of the traditional functionalities of colloidal RC/CL products, the colloidal MCC/alginate (AvicelÕ AC-4125) exhibits an additional range of properties which extend the already broad field of its applications even further.6 These properties include colloidal MCC dispersibility in milk systems, milk gelling properties, dry ingredient blending, and low pH stability (pH 3.5±4.0). MCC has also been coprocessed with high methoxyl (HM) pectin to provide colloidal MCC stabilization in low pH protein-based beverage systems. The MCC/ HM pectin (AvicelÕ BV-2815) provides new and improved colloidal cellulose properties such as low pH stability, fruit pulp suspension, protein stability, emulsion stability, bake stability and colloidal MCC dispersibility in both dairy and non-dairy systems. Potential areas of application include specialty low pH proteinbased beverages, drinkable yogurts and cultured products, fruit sherbets, low pH sauces, baked goods (fruit fillings), and products labeled all natural. The MCC functional properties may also be modified by the proper choice of CMC. Recently, a colloidal grade of MCC coprocessed with a special type of CMC was developed. This product exhibits unique structural properties, i.e., it has a high degree of elasticity indicative of a well-dispersed and stable system. Because of this property, the MCC/CMC (AvicelÕ BV-1518) provides effective low viscosity suspension in neutral beverages (calcium fortified milk, chocolate beverages). In addition to neutral pH beverages, other market opportunities include non-dairy and dairy desserts (texture modification), aerated food systems (foam stability), low pH sauces and dressings (emulsion stability), squeezable mayonnaise (viscosity control), and UHT cooking cream (uniform shelf-life consistency without gelation).

27.3

Nutritional and regulatory information

Nutritionally, microcrystalline cellulose is a carbohydrate and is categorized as an insoluble fiber source. It is non-digestible by humans and hence provides no caloric value. In the US, microcrystalline cellulose has GRAS status and has been used safely in foods for over 30 years. Specifications are provided in the Food Chemicals Codex. In the US it is labeled as cellulose gel. In Europe, microcrystalline cellulose is listed in Annex I of the European Parliament and Council Directive 95/2/EC of March 18, 1995 on Food Additives other than Colours and Sweeteners. It is approved as E460(i) in the list of

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permitted emulsifiers, stabilizers, thickening and gelling agents for use `quantum satis', the level required to achieve a given technological benefit. Purity standards of food grade materials are listed in the EC Directive 98/86/EC. In European markets, MCC is labeled as Cellulose, Microcrystalline Cellulose, or E460. Microcrystalline cellulose has been evaluated by both the EC Scientific Committee for Food (SCF) and the Joint FAO/WHO Expert Committee for Food Additives (JECFA). Both committees determined the maximum Acceptable Daily Intake (ADI) to be `not specified'.7 Microcrystalline cellulose is assigned INS 460 (i) and there are published JECFA specifications. Carboxymethyl cellulose, calcium alginate, high methoxy (HM) pectin, and guar gum are also listed in Annex I of the directive 95/2/EC and are approved for use under numbers E466, E404, E440, and E412 respectively.

27.4

Physical properties

Most stabilizers, viscosifiers, gelling agents, fat mimetics, and textural agents are carbohydrate ingredients based on a starch or gum technology. The utilization of MCC technology to solve food product or processing problems is uniquely different from most hydrocolloids and possesses multi-dimensional properties to provide effective structure, texture, and physical stability in a vast number of food systems. The multi-dimensional nature of MCC ingredients are based on the ability to control viscosity, gelling, surface area, thixotropy, or water binding through an interaction of microcrystalline cellulose with other hydrocolloids and process parameters. The functional properties of MCC based ingredients include suspension of solids, high temperature stabilization, low pH stability in certain instances, emulsion stability, ice crystal control, foam stability, texture modifications, and fat replacement.8 When MCC/hydrocolloid grades are properly dispersed, the cellulose particulates and soluble hydrocolloid set up a network. It is the formation of this insoluble cellulose structural network that provides the functionality. Rheology characterization reveals that the formed gel possesses certain solid-like properties of elasticity which exhibits relatively high yield stresses and a time dependent type of flow behavior. Figure 27.2 illustrates the strain sweep curves (G0 and G00 versus % strain) for a traditional MCC/CMC product. At 2.6% concentration, the strain sweep indicates that the MCC/CMC has a strong gel structure. Figure 27.3 shows that this same MCC/CMC gel is shear thinning and the thixotropic loop shows a high degree of thixotropy. Thixotropic properties impart a variety of desirable characteristics suitable for oil and water emulsions or dispersion type products. Most MCC/hydrocolloid systems are heat stable. Temperature changes have little or no effect on the functionality and viscosity of MCC/CMC dispersions. It is not until temperatures are above 80 ëC, that a slight decrease in viscosity may be detected. This property is extremely important in the preparation of heat stable food products, especially when acids are present. The MCC/hydrocolloid


Fig. 27.2

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Strain sweep curve for traditional MCC/CMC.

Fig. 27.3 Thixotropy of traditional MCC/CMC.

products will hold up under extremely high temperatures including those used during baking, retorting, UHT processing, and microwave heating, with minimal loss in viscosity, consistency, or color.9

27.5

Food applications and functionality

27.5.1 Beverages (suspension of solids) With proper dispersion, coprocessed MCC/hydrocolloids form a unique `cellulose gel' network. This network imparts the functional properties

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Formulation 27.1

An indulgent healthy chocolate beverage

Ingredients

% by weight

Sugar Cocoa Avicel-plusÕ CM 2159 CaCO3 Omega-3 nutritional ingredient Vitamin mix Vanilla flavor Milk flavor Partially skimmed milk

6 1.5 0.45 0.3 0.24 0.2 0.06 0.06 to 100

Procedure 1. Prepare a blend of all dry ingredients. 2. Disperse the blend into milk while stirring until homogeneous. 3. Apply UHT treatment (e.g. preheat 75 ëC, heat: 142 ëC for 4 sec); homogenize 170/ 30 bar. Downstream or upstream homogenization can be alternatively used. 4. Cool down to approximately 10 ëC. 5. Fill aseptically and store (at refrigerated or ambient temperature).

necessary to effectively suspend solids in beverages and other food systems without a significant increase in the viscosity of the product. In an indulgent healthy chocolate beverage (Formulation 27.1), Avicel-plusÕ CM 2159 provides a uniform suspension of cocoa, calcium, and vitamins; it maintains that stability even at ambient temperatures; and it imparts a creamy `mouthfeel'. Formulation 27.2

Calcium fortified, recombined soy beverage

Ingredients Soy protein isolate Sugar Maltodextrin 15 DE Soy bean oil AvicelÕ BV 1518 Tri-calcium phosphate Soy masking flavor Flavor Demineralized (or soft) water

% by weight 3.75 2.00 2.00 1.50 0.40 0.15 0.10 to suit to 100

Procedure 1. Add the sucrose/Avicel blend to process water and mix at high speed for 5 min. 2. Heat mixture to 50 ëC. 3. Add protein and carbohydrate; continue mixing while slowly raising the temperature to 70 ëC. 4. Turn off heat and continue mixing at low±moderate speed for another 15 min. 5. Add fat and calcium, mix at high speed for 2 min. 6. Add flavors and mix for 2 min. 7. UHT: upstream processing; homogenization 200/20 bar, pre-heating 75 ëC, sterilization 140 ëC. 8. Cool product down to 10±15 ëC.


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AvicelÕ BV 1518, coprocessed with a special type of CMC, creates a uniquely different structure which has added surface charge. It has demonstrated significant improvements in its functional properties, e.g., low viscosity suspension, low pH stability, salt stability, and a high degree of elasticity. In a calcium fortified, recombined soy beverage (Formulation 27.2), AvicelÕ BV 1518 will provide excellent long-term suspension and shelf stability at ambient temperatures at very low viscosity, similar to that of plain soymilk. In certain regional target applications, the ingredient makes it easy to re-suspend large volumes of insoluble particulates. 27.5.2 Beverages (high temperature stability) A specialized coprocessed AvicelÕ RT 1133 was developed to provide rheology stability under retort processing. Use of this ingredient allows the manufacturer to meet and exceed the thermal Fo death time requirements of retort sterilization Formulation 27.3

Retorted adult nutritional beverage

Ingredients Corn syrup solids 24 DE Sucrose, dry granular Skim milk powder Corn oil Soy protein isolate Cocoa, red dutched Cocoa, natural AvicelÕ RT 1133 Potassium citrate, monohydrate Soy lecithin Natural and artificial vanilla flavor Potassium chloride Dipotassium phosphate Vitamin/mineral premix Calcium carbonate Sodium chloride ViscarinÕ GP 209 carrageenan Water

% by weight 8.600 6.600 3.300 2.500 0.710 0.600 0.600 0.5±0.8 0.300 0.280 0.250 0.230 0.200 0.103 0.100 0.070 0.01±0.02 to 100

Procedure 1. Disperse AvicelÕ RT 1133 stabilizer in water using medium shear (a propeller-type mixer) for 10 min. 2. Dry blend vitamins, minerals, proteins and ViscarinÕ GP 209F carrageenan. Add to above dispersion and continue mixing for 30 min. 3. Add oil and all remaining ingredients. Mix for 5 min. 4. HTST process at 80 ëC (175 ëF) for 3 s. 5. Homogenize beverage at 3500 psi (3000 1st and 500 2nd). 6. Bottle and rotary retort to the appropriate F0 value. Cool to 32 ëC (90 ëF). 7. Alternatively, static retort at 118 ëC (245 ëF) and 15 psi for 20±30 min. On removal from retort, shake bottles to disrupt any localized gel structure. Continue to shake several times while cooling.

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while minimizing total process time. This is especially important in static retort processing where overall product `thickening' may occur; the net result of which may reduce heat penetration and thereby increase the process time required. This product provides a low viscosity-suspending network, particularly useful in retorted/canned, and UHT/retort processed beverages and foods. See Formulation 27.3 for an example. 27.5.3 Beverages (low pH stability) For low pH protein beverages the stability requirements for suspension are more complicated. AvicelÕ BV 2815 consists of MCC coprocessed with high methoxyl pectin. It provides superior stability and viscosity control when compared to other stabilizers, such as pectin, xanthan gum, and propylene glycol alginate, in many of today's high growth markets, including soy-based drinks, drinkable yogurts, functional drinks, energy drinks, and fluid milk products. Formulation 27.4 Ingredients

Acidified milk-juice beverage % by weight

Skim milk 20.00 Sugar 8.00 Orange juice concentrate 4.21 Nonfat dry milk 1.73±5.03 0.40 AvicelÕ BV 2815 HM pectin 0.35 Citric acid 0.25±0.40 Water to 100 (The pH of the finished product ranges between 4.0 and 4.3) Procedure Phase I (Juice/stabilizer) 1. Blend orange juice concentrate and water. 2. Disperse AvicelÕ BV 2815 in orange juice/water mixture; heat to 145 ëF (63 ëC) and continue mixing for 15 min. 3. Add pectin and continue mixing for 10 min. 4. Add citric acid; mix until hydrated ± approximately 5 min. Phase II (Milk protein) 1. Dry blend non-fat dry milk and sugar. 2. Add to skim milk at ambient temperature; heat slowly to 145 ëF (63 ëC); mix for 20 min. 3. Maintain temperature throughout formula assembly at 145 ëF (63 ëC). Cool both phases to ~ 110 ëF (43 ëC), then Add Phase II (Milk protein) into Phase I (Juice/stabilizer) Reduce foaming by adding antifoam. Process: 1. Ultra-pasteurize to 195 ëF (90 ëC) for 15 s; cool to 165 ëF (74 ëC). 2. Homogenize at 2500 psi or 172 bar (two-stage: 2000 psi/500 psi; 138 bar/34.5 bar). 3. Cool to 45 ëF (7 ëC); fill into desired packaging.


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This MCC/HM pectin can be activated with low shear in the protein phase, the make-up water, or in the low pH phase including juice and juice concentrates. Order of addition and the process conditions must be chosen carefully in order to provide protein protection and full shelf-life stability. At protein levels ranging from 3±7 g/8 oz serving in milk-juice, acidified soyjuice, or whey-juice beverages, this product provides long-term stability at lower stabilizer use levels to achieve suspension. Pectin by itself may appear stable as it has minimal serum separation. However, higher levels may be needed to prevent sedimentation over time, especially at higher protein levels, which may result in higher viscosity beverages. Pectin as a sole stabilizer may not provide complete stability in low pH, high protein beverages, and can result in sedimentation. AvicelÕ BV 2815 consists of MCC and pectin, which may both be considered natural. Additional HM pectin is most often added in combination with MCC/HM pectin to provide complete and effective stability over the entire expected product shelf-life. See Formulation 27.4 for an example of an acidified milk-juice beverage. 27.5.4 Dressings, sauces, and cooking cream (emulsion stability) Effective stabilization against the coalescence of oil globules in an emulsion system can be obtained utilizing the `cellulose gel' network. MCC functions as an emulsion stabilizer and thickener because of the strong affinity cellulose has for both oil and water. This results in an orientation of solid particulates at the oil-in-water interface.10 In addition, the viscosity developed by the MCC/ hydrocolloid products acts to thicken the water phase between the oil globules preventing their close approach and subsequent coalescence. This combined functional effect can be utilized to stabilize emulsions and dispersions in food products under adverse process and storage conditions. Avicel-plusÕ CM 2159 and Avicel-plusÕ SD 4422 prevent separation of cream during shelf-life at temperatures up to 40 ëC and improve cooking stability under difficult conditions, e.g., wine sauce. Creams with different viscosities can be created by using the appropriate Avicel-plusÕ stabilizer, e.g. Avicel-plusÕ SD 4422 provides high hot viscosity and improved cling to pasta dishes. The ingredients enable the possibility to create fat reduced recipes with health benefits for the consumer and offer a cost reduction for the manufacturer. Formulation 27.5 provides an example. 27.5.5 Vegetable fat whipping cream (foam stability, syneresis control, fat replacement) In aerated food systems, foam stability depends primarily on the types of additives present and their ability to produce the necessary structural strength in preventing the coalescence and subsequent collapse of the air bubbles. MCC is not a whipping aid or film-forming material, but it does provide effective foam stabilization in a variety of whipped and/or aerated food systems. MCC disper-

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Formulation 27.5

UHT dairy cooking cream

Ingredients Cream, 40% fat Functional native tapioca starch* Emulsifier E 471 Avicel-plusÕ Stabilizer Flavor Skimmed milk

5% fat formula, wt%

20% fat formula, wt%

12.5 2.0±2.5 0.2 see Table 27.1 to suit to 100

50 1.0±2.5 0.2 see Table 27.1 to suit to 100

*for UHT processing Procedure 1. Blend all dry ingredients and add to a mix of cream and milk. 2. Pre-heat to 75 ëC (167 ëF). 3. Homogenize at 100/20 bar (approx. 1500/250 psi). 4. UHT treatment at 140 ëC (284 ëF) for 3 to 5 s. 5. Cool to 15 ëC (59 ëF) and fill aseptically.

Table 27.1

Viscosities obtained at different fat levels

Stabilizer with 2% starch

Viscosity*, cP 12% fat 5% fat

18 to 20% fat

30% fat

0.35% Avicel-plusÕ CM 2159

1,500±2,500

5,000±6,000

12,000±14,000

25,000±30,000

0.70% Avicel-plusÕ SD 4422

4,000±5,000

9,000±11,000

16,000±18,000

NA

* Viscosity measurement at 4 ëC: Brookfield equipped with spindle#2, speed 12 rpm, measured after 1 minute.

sions act to thicken the water phase between air cells and provide added structural integrity to the protein film surrounding the air cells. The cellulose gel network created improves the body and texture, foam stiffness, and stability of both dairy and non-dairy type whipped topping products. In addition, MCC is effectively used to stabilize mousse products, marshmallow toppings, confectionery products, and controls overrun in frozen desserts.8 The inherent rheological properties of cellulose gel dispersions allow the MCC/hydrocolloid products to be utilized in many reduced fat or nonfat food applications. The consistency of oil-in-water emulsions can vary from a thin fluid material at low oil levels, to a thick viscous paste at very high oil levels. The water-holding capacity of the cellulose gel network and the thixotropic nature of the gels allows the majority of oil/fat to be removed while maintaining the required rheological and textural properties found in the full fat counterpart of these same food products.11


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AvicelÕ can be blended with other dry ingredients and added directly to the water phase, allowing a straightforward use, requiring no pre-hydration. The MCC can stabilize the liquid cream emulsion, preventing phase separation and maintaining a constant viscosity during shelf-life. It further insures a short whipping time and will generate a smooth whipped cream with excellent foam stiffness and stability. MCC provides perfect syneresis control of whipped cream, prevents foam collapse, and improves freeze thaw stability. An example of a vegetable fat whipping cream is given in Formulation 27.6.

Formulation 27.6

Vegetable fat whipping cream

Ingredients Fat phase Hydrogenated vegetable oil Lactic acid ester of mono-diglycerides of fatty acids Tartaric acid ester of mono and diglycerides of fatty acids De-oiled soybean lecithin Aqueous phase Sugar Sorbitol (70% solids in water) Sodium caseinate AvicelÕ BV 1518 Avicel-plusÕ GP 3419 Di-potassium phosphate Flavor Water

27% Fat, wt %

22% Fat, wt %

27.00 0.50 0.20

22.00 0.70 0.20

0.10

0.10

11.00 0.80 0.70 0.45

11.00 0.80 0.70

0.10 0.05 to 100

0.45 0.10 0.05 to 100

Procedure 1. Gently and completely melt the vegetable fat at 70 ëC then add the emulsifiers and ensure a clear and homogeneous solution is obtained. 2. Dry blend the Avicel, Na-caseinate and phosphate. Sugar can be blended with these ingredients or added separately to the water phase. 3. Disperse this blend in hot water (about 70 ëC) for 10 min with intensive mixing (e.g. with a high speed propeller mixer or a rotor stator mixer). Water hardness should be as low as possible. If hard water is used, a sequestrant should be included in the water phase, e.g. 0.2% tri-sodium citrate (E331). 4. Add sorbitol and flavors to the water phase and mix intensively for 5 min. 5. Make a pre-emulsion by slowly adding the oil phase to the water phase while stirring continuously for 5 min. 6. UHT process by pre-heating to 70±80 ëC, sterilizing at 142 ëC for 4 s, cooling to 70± 80 ëC, homogenizing at 180/20 bar then cooling product rapidly to 5 ëC. 7. Allow product to maturate (aging) for 24 hours at 4 ëC. Note: As with all vegetable fat whipping creams, storage should be between 4 and 7 ëC in a dry place and should never exceed 20 ëC.

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27.5.6 Whipping process Creams should be whipped at 4±7 ëC using a kitchen type mixer (e.g. HobartÕ, KitchenaidÕ, KenwoodÕ). During whipping, overrun and foam stiffness will increase in parallel up to a maximum level. Thereafter further whipping will reduce the overrun and lead to phase inversion. With some stabilizers the structure is developed during whipping causing the cream to form a consistent mass on the whisk. This requires continuous visual inspection of the whipping process to determine the optimum whipping time. Creams with Avicel develop their texture immediately after whipping due to its unique thixotropy. Therefore visual inspection is not necessary and the whipping process should be stopped after the designated whipping time, e.g. 2 to 3 minutes (see Table 27.2). Table 27.2 (a) AvicelÕ charcteristics Purpose

Declaration

AvicelÕ BV 1518

Stabilization of regular (27% fat) whipping creams

Avicel-plusÕ GP 3419

Stabilization of reduced fat (22% fat) whipping creams

Cellulose (E460), Cellulose gum (E466) Sugar added for standardization Calcium chloride added as a carrier Cellulose (E460), Cellulose gum (E466) Sugar added for standardization

(b) Typical product characteristics Characteristic

Comments

Cream pH Cream viscosity stability Emulsion stability at 40 ëC, 1 week Whipping time Foam stiffness (SMS Texture Analyzer) Foam stiffness stability Overrun Syneresis (water drainage) Freeze thaw stability

6.5±6.7 No significant increase after 8 weeks at 4 ëC Good (no phase separation) 2±2.5 min, KitchenaidÕ at max speed 120±150 g No decrease after 24 h at 20 ëC 300±400% None after 24 h at 20 ëC Good

27.5.7 Ice cream (heat shock stability, ice crystal control) Microcrystalline cellulose has been used for many years in frozen desserts. It was first formulated into fat-free ice cream in the early 1960s to replace the lost eating qualities resulting from the removal of butterfat. Since these earlier applications, the quality of MCC colloidal products has advanced providing broader stability solutions to ice cream. Manufacturers are constantly confronted with the need to minimize shelf-life defects (mainly ice crystal development)


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and transportation concerns (altitude protection). Process improvements, cost reduction, and improved eating quality also require constant consideration. Sufficient shear forces are required in order to properly disperse colloidal grades of MCC in ice cream mix. Homogenization pressures upwards of 2,500 psi are typically recommended. Recent developments by FMC Corporation have significantly reduced the homogenization requirements to less than 1,500 psi. Properly hydrated, MCC imparts a unique stabilization mechanism into the ice cream mix. Dairy proteins and MCC interact to form stable matrices capable of eliminating whey separation in resale mix and melted ice cream. This physical complex also adds considerable integrity to the air cells translating to improved protection against altitude abuse and to a better and more uniform melt down behavior. Newly developed forms of microcrystalline cellulose provide resistance to the coalescence of air cells in ice cream during heat shock. The value is reflected in smoother and creamier textures, controlled melt, and altitude protection. The light photomicrographs (Figs 27.4 and 27.5) reveal the improvements in air cell integrity. Figure 27.4 represents the newest form of colloidal MCC compared to the standard grades of MCC in Fig. 27.5. Heat shock protection is a major concern for manufacturers. MCC is the only stabilization system that relies on insolubility to assist in the inhibition of ice crystal growth.12 As a result of freeze concentration, the serum phase of the frozen ice cream is highly concentrated with MCC. The concentration of MCC sols produce strong elastic gels capable of restricting water migration and setting up physical barriers to the onset of larger ice crystals during abusive temperature

Fig. 27.4

Low-fat ice cream air cell integrity with new colloidal MCC.

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Fig. 27.5

Low-fat ice cream air cell structure with standard MCC.

conditions. Highly structured serum phases stabilized with MCC are also responsible for rich mouthfeel and melt resistance. Quality improvements such as these are often the focus of formulations low in fat, low in solids, and/or low in sugar. Historically, consumer acceptance of lean ice cream formulations such as reduced/low fat, reduced sugar, and reduced milk solids not fat (MSNF) has been poor. The removal of solids from ice cream formulations can partly be replaced with sugar alcohols, and other bulking agents. These alone will not impart the needed solids replacement to match the mouthfeel and texture of the finished product. Unlike many other hydrocolloids typically used in frozen desserts, MCC imparts the rheological properties of a higher solids formula. This translates into the perception of a more full bodied texture even at lower total solids. The solids-like properties of microcrystalline cellulose also make it a useful additive in novelty applications where shape retention is lacking. For example, ice cream sandwiches and extruded bars can be produced with short textures providing clean cuts and well defined impressions. A formula for a lowfat frozen dessert is given in Formulation 27.7. 27.5.8 Non-colloidal MCC (bulking agent, fat replacer, flow aid, tablet excipient) The powdered non-colloidal grades of microcrystalline cellulose (AvicelÕ PH) are white, odorless, tasteless, relatively free-flowing powders that were originally used as sources of fiber in low calorie foods or as a flow aid for

Microcrystalline cellulose Formulation 27.7

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Low fat ice cream

Ingredients Sugar Milk solids nonfat Corn syrup solids 36 DE Butterfat Whey solids GelstarÕ IC 3542 Stabilizer System: [Colloidal MCC/CMC, mono, diglycerides polysorbate 80, carrageenan] Total solids

% by weight 12.0 9.0 8.0 4.0 3.0 0.5±0.6 36.55

Procedure 1. Disperse the GelstarÕ IC 3542 stabilizer into the mix at the point of greatest agitation to prevent clumping and promote better incorporation. To minimize processing viscosity, add GelstarÕ IC 3542 into the milk and cream. When preparing concentrated dispersion of GelstarÕ stabilizer in milk, do not exceed 2% concentration in order to minimize the dispersion viscosity. Note: When preparing reconstituted formulations, add milk powder prior to adding GelstarÕ IC 3542. For best results, add the stabilizer slowly into the milk while mixing with a high speed blender to avoid clumping and ensure optimum functionality of the stabilizer. 2. Pasteurize and homogenize according to established guidelines: 2,000/500 psi and HTST at 80 ëC or 175 ëF for 25 s. Good homogenization is important to activate the stabilizer. 3. Cool mix to 40 ëF (8 ëC) and age for a minimum of 4 hours for more effective freezing and crystallization of the butterfat. 4. Freeze and package. 5. Rapid hardening assures minimal ice crystal formation.

grated cheese. These later found wide acceptance within the pharmaceutical industry for use as a binder/excipient in direct compression tablets. The PH grades are insoluble, chemically inert, and crystalline in nature with a very high degree of porosity. More recently, small particle sized MCC (AvicelÕ LM-310), less than about 30 microns, have been used in foods as bulking agents and as fat substitutes. The particles are considerably smooth, having a high absolute density, a high loose bulk density (>0.40 g/cc), a low degree of oil absorptivity (1 (FG ÿ FMGM)/FGGM, which has shown to correlate well with gelling properties (see Section 29.5.1). It is important to realize that in a population of alginate molecules, neither the composition nor the sequence of each chain will be alike. This results in a compositional distribution of a certain width. 29.3.2 Source dependence Commercial alginates are produced mainly from Laminaria hyperborea, Macrocystis pyrifera, Laminaria digitata, Ascophyllum nodosum, Laminaria japonica, Eclonia maxima, Lessonia nigrescens, Durvillea antarctica and Sargassum spp. Table 29.1 gives some sequential parameters (determined by high field NMR spectroscopy) for samples of these alginates. The composition and sequential structure may, however, vary according to seasonal and growth conditions (Haug, 1964; Indergaard and SkjaÊk-Brñk, 1987). Generally, a high content of -L-guluronic acid is found in alginate prepared from stipes of old Laminaria hyperborea plants. Alginates from A. nodosum, L. japonica and Macrocystis pyrifera are characterised by a low content of G-blocks and a low gel strength. Alginates with more extreme compositions can be isolated from bacteria (SkjaÊk-Brñk et al., 1986) which can contain up to 100% mannuronate. Bacterial alginates are also commonly acetylated. Alginate with a very high content of guluronic acid can be prepared from special algal tissues such as the outer cortex of old stipes of L. hyperborea (see Table 29.1), by chemical fractionation (Haug and Smidsrùd, 1965; SkjaÊk-Brñk et al., 1986) or by enzymatic modification in vitro using mannuronan C-5 epimerases from A. vinelandii (ErtesvaÊg et al., 1999). This family of enzymes is able to epimerise M-units into G-units in different patterns from almost strictly alternating to very long G-blocks. The Table 29.1

Composition and some sequential parameters of algal alginates

Source Laminaria japonica L. digitata L. hyperborea, leaf L. hyperborea, stipe L. hyperborea, outer cortex Lessonia nigrescens Ecklonia maxima Macrocystis pyrifera Durvillea antarctica Ascophyllum nodosum, fruiting body Ascophyllum nodosum, old tissue

FG

FM

FGG

FMM

FGM,MG

0.35 0.41 0.55 0.68 0.75 0.38 0.45 0.39 0.29 0.10 0.36

0.65 0.59 0.45 0.32 0.25 0.62 0.55 0.61 0.71 0.90 0.64

0.18 0.25 0.38 0.56 0.66 0.19 0.22 0.16 0.15 0.04 0.16

0.48 0.43 0.28 0.20 0.16 0.43 0.32 0.38 0.57 0.84 0.44

0.17 0.16 0.17 0.12 0.09 0.19 0.32 0.23 0.14 0.06 0.20

812


epimerases from A. vinelandii have been cloned and expressed, and they represent at present a powerful new tool for the tailoring of alginates. Commercial alginates with less molecular heterogeneity, with respect to chemical composition and sequence, can also be obtained by a treatment with one of the C-5 epimerases. 29.3.3 Molecular weight Alginates, like polysaccharides in general, are polydisperse with respect to molecular weight. This may arise for two different reasons: (i) polysaccharides are not directly coded for by the DNA, but are synthesised by polymerase enzymes, and (ii) a depolymerisation occurs during extraction. Due to this polydispersity, the `molecular weight' of an alginate becomes an average over the total distribution of molecular weights. There are several methods for averaging the molecular weight, the two most n (which weighs the polymer molecules common are the number-average, M according to the number of molecules in a population having a specific w (which weighs the polymer molecular weight), and the weight-average, M molecules in a population according to the weight of molecules having a specific n is called the polydispersity index (PI). A w =M molecular weight). The fraction M PI of less than 2.0 suggests that some fractionation has occurred during the production process. Precipitation, solubilisation, filtration, washing or other separating procedures may have caused loss of the high or the low molecular weight tail of the distribution. A PI of more than 2.0 indicates a wider distribution, and suggests that blending of different batches with different molecular weights to obtain a sample of a certain average molecular weight (viscosity) or that a non-random degradation of the polymer has taken place. The molecular weight distribution can have implications for the uses of alginates, as low molecular weight fragments containing only short G-blocks may not take part in gel network formation and consequently not contribute to the gel strength. Also, in some high-tech applications, the leakage of mannuronate-rich fragments from alginate gels may cause problems (Stokke et al., 1991; Otterlei et al., 1991). 29.3.4 Selective binding of ions The ion-binding characteristics of alginates represent the basis for their gelling properties. Alginates show characteristic ion-binding properties in that their affinity for multivalent cations depends on their composition (Haug, 1964). These characteristic affinities are exclusive to polyguluronate; polymannuronate is almost without selectivity. The affinity of alginates for alkaline earth metals increases in the order Mg 1). An important feature in the diffusion setting method is that the final gel can exhibit an inhomogeneous distribution of alginate, with the highest concentration at the surface and gradually decreasing towards the centre of the gel. Extreme alginate distributions have been reported (SkjaÊk-Brñk et al., 1989a) with a five-fold increase at the surface (from the concentration in the alginate solution prior to gelation) and virtually zero concentration in the centre. This result has been explained by the fact that diffusion setting will create a sharp gelling zone moving from the surface towards the centre of the gel. The activity of alginate (and of the gelling ion) will equal zero in this zone, and alginate molecules will diffuse from the internal, non-gelled part of the gelling body towards the zero activity region. It is important to know that the degree of homogeneity can be controlled, and how different parameters can govern the final alginate distribution. Maximum inhomogeneity is obtained by letting a low molecular weight alginate gel at low concentration of the gelling ion and in the absence of non-gelling ions. Maximum homogeneity is reached by gelling a high molecular weight alginate in the presence of high concentrations of both gelling and non-gelling ions (SkjaÊk-Brñk et al. 1989a). Non-gelling ions are

Alginates 821 also important with respect to the stability of the gels. It has been shown that alginate gels start to swell markedly when the ratio between non-gelling and gelling ions becomes too high, and that the observed destabilisation increases with increasing FM (Martinsen et al., 1989). Internal setting As outlined earlier, this technique is based on addition of an inactive form of the crosslinking ion into an alginate solution. In the case of calcium the insoluble CaCO3 or the slightly soluble CaSO4 may be used, or the Ca2+ ions may be complexed in a chelating agent (EDTA, citrate, etc.). The activation of the crosslinking ions is usually linked to a change in pH caused by the addition of organic acids or lactones. Lowering of the pH readily releases Ca2+ from CaCO3 and complexing compounds. Chelating agents do, however, have discrete pH ranges where the complexed ions are released; in the case of EDTA, pH has to be lowered to around 4.0 to obtain a release of calcium ions. By using salts like CaCO3 and CaSO4, gels can be prepared over a much wider pH range (Draget et al., 1991). The main difference between internal and diffusion setting is the gelling kinetics. Internal setting allows for the tailoring of an alginate gelling systems towards a given manufacturing process. For example, in the alginate/CaCO3/Dglucono--lactone (GDL)-system, reducing the average particle size of the carbonate, and thereby increasing the total surface available to the acid, reduces the transition time (Draget et al., 1991). The modulus of the final gel, however, approaches the same value independent of gelling kinetics. Other mediators can be necessary for the control of gelling kinetics. In the case of CaSO4, the solubility is so high that gelation would occur spontaneously if complexing agents such as polyphosphates were not present. Internal setting almost always gives homogeneous gels, except where a low viscosity solution allows particle sedimentation. The gel strength of internally set alginate gels depends more on molecular weight compared to gels set by diffusion (Draget et al., 1993). Whereas gels made by the latter method describe almost a step function where gel strength becomes independent of molecular weight at around 100 kDa (Smidsrùd, 1974) (weight average degree of polymerisation, DPw ~ 500), the internally set gels still depend on molecular weight even at 300 kDa (DPw ~ 1,500). This is, at least partly, due to the fact that the internally set gels are calcium limited compared to the gels made by diffusion, implying that the non-elastic fraction (sol and loose ends) will be higher in the internally set gels at a given molecular weight. Observations have shown that the internally set gels are more exposed to syneresis than gels set by diffusion. As a rule of the thumb, [Ca2+] 0.5[G] represents the limit at which syneresis becomes prominent in internally set gels (Draget et al., 1991). There is no detailed understanding of this difference at the moment, but part of the explanation is certainly the different modes of gelation. Diffusion setting gives a gelling zone, moving towards the centre of the gelling

822


body, where the alginate molecules become saturated with Ca2+ and their activity drops towards zero. Internal setting implies a process where gelling starts simultaneously at a large number of locations. This puts some topological strains on the alginate molecules, but their activity and translational mobility does not equal zero. One can therefore imagine that after the primary gel network has been formed, elastic segments with free G-blocks will still be present that could create new junction zones given the proximity of another free G-block and the presence of calcium ions. Thus, if the concentration of Ca2+ increases, a second class of junction zones may therefore be formed which will contract the gel network resulting in volume reduction. 29.5.2 Alginic acid gels It has been known and utilised for several decades that alginates precipitate at pH below the pKa value (Haug, 1964). In fact, the discovery that alginates were block co-polymers originated from the discovery that the different types of blocks had different solubility at low pH. It is also well known that, under controlled conditions, alginates may form acid gels at these low pH. These acid gels are, however, far less studied than the ionically crosslinked alginate gels, and with the exception of some pharmaceutical recipes (e.g. the anti-reflux agent Gaviscon), the number of applications is rather limited. The preparation of an alginic acid gel has to be performed with care. Direct addition of a mineral acid to, e.g., a Na-alginate solution leads to an instantaneous precipitation rather than a gel. pH must therefore be lowered in a controlled fashion, and this is most conveniently carried out by the addition of slowly hydrolysing lactones like Dglucono--lactone (GDL). It has been shown (Draget et al., 1994) that gel strength of acid gels prepared by this method becomes independent of pH below 2.5. GDL is added as dry powder, and a sol/gel transition is observed within 30± 60 minutes, depending on the chemical composition and molecular weight of the alginate. The strength of the acid gels is more or less independent on the method by which they are made; acid gels thus seem to be independent of the history of formation. An important difference between the acid gels and the ionically crosslinked gels seems, therefore, to be that the former behave more as being of an equilibrium nature. If acid gels are made from alginates with different chemical composition, it has been found that these gels resemble ionic gels in the sense that a high content of guluronate (high values of NG>1) give the highest moduli. But in contrast to ionic gels, also poly-mannuronate sequences support acid gel formation. Poly-alternating sequences seem to perturb gel formation in both cases. The obvious demand for homopolymeric sequences in acid gel formation suggests cooperative processes to be involved just as in the case of ionic gels. A broad molecular weight dependence has been observed, and this dependence becomes more pronounced with increasing content of guluronic acid residues.

Alginates 823

29.6

Foods, nutrition and health

29.6.1 Applications in food products Some examples of the use of alginates in food products have already been given in the previous chapters. Their ability to improve, modify and stabilise the texture of foods represents the basis for applying alginates as food additives, e.g. as a viscosity enhancer, gel former and in the stabilisation of aqueous mixtures, dispersions and emulsions in general. Alginates are also used to control the melting behaviour of ice cream. Most applications are based on the physical properties of alginates themselves, but may also result from interactions with other components of the food product, e.g. proteins or fibres. For detailed descriptions and formulation, see Cottrell and Kovacs (1980), Sime (1990) and Littlecott (1982). Restructured food based on Ca-alginate gels is simple (gelling being independent of temperature), and it is a steadily growing alginate application. Such processes are based on binding together a flaked, sectioned, chunked or milled foodstuff to make it resemble the original. Examples of such products already on the market are meat products (both for human consumption and as pet-food and feed), onion rings, pimento olive fillings, crabsticks and cocktail berries. The synergetic gelling between alginates high in guluronate and highly esterified pectins may be utilised for the use in jams, jellies, fruit fillings, etc. (Toft et al., 1986). These mixed alginate/pectin systems may give thermoreversible gels in contrast to the purely ionically crosslinked alginate gels. Such gels are also almost independent of sugar content, in contrast to pectin gels, and may therefore be used in low calorie products. As already mentioned, propylene glycol alginate is the only alginate derivative used in food products. The main advantage of PGA is that it may be used to stabilise liquids under acidic conditions where the unmodified alginate would precipitate. 29.6.2 Nutritional aspects and health benefits Alginates as such are regarded as essentially non-digestible in the human gastrointestinal (GI) tract and are classified as so-called poorly fermentable soluble (viscous) fibres (Brownlee et al., 2005). Hence, they can not act as a direct source of energy but may provide other health-related benefits. Such soluble dietary fibres do in general reduce the rate of small intestinal absorption of nutrients (Jenkins et al., 2000), which in turn may reduce the likelihood of cardiovascular diseases (by reducing the overall cholesterol levels) as well as the onset of diabetes type II (by reducing the glycaemic load). Specific to alginates, it has been shown (Sunderland et al., 2000) that, to a large extent, they can inhibit the activity of proteases. As outlined in Section 29.4.2 it has been shown that alginates high in mannuronate stimulate the production of cytokines in vitro. It has not been proven that an oral administration of such alginates would result in a general immuno-response in humans, but it has been suggested that they could enhance the repair of mucosal damage in the GI tract (Brownlee et al. 2005).

824


The fact that alginate also may undergo a sol-gel transition may be exploited to reduce the overall energy intake by stimulating endogeneous satiety signalling (Pelkman et al., 2007) and that the products for this type of application can be formulated as a calcium-gelled fibre beverage. It has also been shown that microencapsulation (see Section 29.5.1) of probiotic bacteria has a profound effect on improved survival rates when such bacteria are exposed to acids and bile salts (Ding and Shah, 2007). Finally, it has also been proposed that the highly specific ion binding properties of the alginate molecule (see Section 29.3.4) could represent a way to reduce the damage of ingested radioactive strontium isotopes following a nuclear accident. One study (Beresford et al., 1999) shows that when 5% calcium alginate is incorporated into the diet of dairy goats, the transfer of radioactive Sr into the milk was reduced by approximately 50%.

29.7

Regulatory status

The safety of alginic acid and its ammonium, calcium, potassium, and sodium salts were last evaluated by the Joint FAO/WHO Expert Committee on Food Additives (JECFA) at its 39th meeting in 1992. An ADI `not specified' was allocated. JECFA allocated an ADI of 0±70 mg/kg bw to propylene glycol alginate at its 41st meeting in 1993. In the US, ammonium, calcium, potassium, and sodium alginate are included in a list of stabilisers that are generally recognised as safe (GRAS). Propylene glycol alginate is approved as a food additive (used as an emulsifier, stabiliser or thickener) and in several industrial applications (coating of fresh citrus fruit, as an inert pesticide adjuvant, and as component of paper and paperboard in contact with aqueous and fatty foods). In Europe, alginic acid and its salts and propylene glycol are all listed as EC approved additives other than colours and sweeteners. Alginates are inscribed in Annex I of the Directive 95/2 of 1995 and as such can be used in all foodstuffs under the quantum satis principle in the EU (with the exception of those cited in Annex II and those described in article II of the Directive). A general prohibition exists on the use of alginate (as well as against several other gelling biopolymers) in so-called jelly mini-cups (amendment of 2005). Propylene glycol alginate (PGA) is inscribed in Annex IV (òther permitted additives') of the directive with a maximum level ranging from 0.1 mg/l±10 g/l (1.2±8 g/kg) depending on the food product.

29.8

Future trends

Containing only the two monomer units M and G linked by the same 1,4 linkages, the alginate molecule may look very simple. This may have lead potential commercial users of alginate to treat alginate as a commodity in much the same way as many of the cellulose derivatives. But as already outlined,

Alginates 825 alginates exhibit a very high diversity with respect to chemical composition and monomer sequence resulting in a large variety of physical and biological properties. So, contrary to what may be expected by just looking at the monomer composition, the family of alginate molecules represents a challenge to the unskilled users of alginate, but an advantage for those end-users of alginate aiming at research-based, high value applications. The possibility of the tailoring of alginates to fit new and demanding applications is increased even further if epimerase-modified alginates are taken into consideration. It is therefore possible to foresee a future trend, which has already started, where the exploitation of alginate gradually shifts from low-tech commodity applications with increasing competition from low-cost alternatives, to more advanced knowledge-based applications in the food, pharmaceutical and biomedical areas.

29.9

References and sources of further reading

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Alginates 827 and MALONE DM, Èffects of sterilization treatments on some properties of alginate solution and gels', Biotechnol Prog, 1990 6 51±53. LINKER A and JONES RS, À new polysaccharide resembling alginic acid isolated from Pseudomonas', J Biol Chem, 1966 241 3845±3851. LITTLECOTT GW, `Food gels ± the role of alginates', Food Technol. Aust., 1982 34 412± 418. MACKIE W, PEREZ S, RIZZO R, TARAVEL F and VIGNON M, Àspects of the conformation of polyguluronate in the solid state and in solution', Int J Biol Macromol, 1983 5 329±341. Ê K-BRáK G and SMIDSRéD O, Àlginate as immobilization material: I. MARTINSEN A, SKJA Correlation between chemical and physical properties of alginate gel beads', Biotechnol Bioeng, 1989 33 79±89. NEISER S, DRAGET K and SMIDSRéD O, `Gel formation in heat-treated bovine serum albumin±sodium alginate systems', Food Hydrocolloids, 1997 12 127±132. NEISER S, DRAGET KI and SMIDSRéD O, Ìnteractions in bovine serum albumin±calcium alginate gel systems', Food Hydrocolloids, 1998, 13, 445±458. ONSéYEN E, `Commercial applications of alginates', Carbohydr Eur, 1996 14 26±31. Ê K-BRáK G, SMIDSRéD O, SOON-SHIONG P and ESPEVIK T, OTTERLEI M, éSTGAARD K, SKJA Ìnduction of cytokine production from human monocytes stimulated with alginate', Int J Immunother, 1991 10 286±291. PAINTER TJ, SMIDSRéD O and HAUG A, À computer study of the changes in compositiondistribution occurring during random depolymerisation of a binary linear heteropolysachharide', Acta Chem Scand, 1968 22 1637±1648. PARSONS BJ, PHILLIPS GO, THOMAS B, WEDLOCK DJ and CLARK-STURMAN AJ, `Depolymerization of xanthan by iron-catalysed free radical reactions', Int J Biol Macromol, 1985 7 187±192. PELKMAN CL, NAVIA JL, MILLER AE and POHLE RJ, `Novel inatake dietary clacium-gelled, alginate-pectin beverage reduced energy in nondieting overweight and obese women: interactions with restraint status', Am J Clin Nutr, 2007 86 1595±1602. PENMAN A and SANDERSON GR, À method for the determination of uronic acid sequence in alginates', Carbohydr Res, 1972 25 273±282. SADOFF HL, Èncystments and germination in Azotobacter vinelandii', Bacteriol Rev, 1975 39 516±539. SIME W, Àlginates', in: Food Gels (Harris P, ed.), London: Elsevier, 1990, pp. 53±78. SIMENSEN MK, DRAGET KI, ONSéYEN E, SMIDSRéD O and BORE TF, Ùse of G-block polysaccharides', Patent WO/1998/002488, 1998. Ê K-BRáK G, SMIDSRéD O and LARSEN B, `Tailoring of alginates by enzymatic SKJA modification in vitro', Int J Biol Macromol, 1986 8 330±336. Ê K-BRáK G, GRASDALEN H and SMIDSRéD O, Ìnhomogeneous polysaccharide ionic SKJA gels', Carbohydr Polym, 1989a 10 31±54. Ê K-BRáK G, MURANO E and PAOLETTI S, Àlginate as immobilization material. II: SKJA Determination of polyphenol contaminants by fluorescence spectroscopy, and evaluation of methods for their removal', Biotechnol Bioeng, 1989b 33 90±94. SMIDSRéD O, `Some physical properties of alginates in solution and in the gel state', Thesis, Norwegian Institute of Technology, Trondheim, 1973. SMIDSRéD O, `Molecular basis for some physical properties of alginates in the gel state', J Chem Soc Faraday Trans, 1974 57 263±274. SMIDSRéD O, `Structure and properties of charged polysaccharides', Int Congr Pure Appl Chem, 1980 27 315±327. LEO WJ, MCLOUGHLIN AJ

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and SKJAÊK-BRáK G, Àlginate as immobilization matrix for cells', Trends Biotechnol, 1990 8 71±78. SMIDSRéD O and WHITTINGTON SG, `Monte Carlo investigation of chemical inhomogeneity in copolymers', Macromolecules, 1969 2 42±44. SMIDSRéD O, HAUG A and LARSEN B, `Degradation of alginate in the presence of reducing compounds', Acta Chem Scand, 1963 17 2628±2637. SMIDSRéD O, HAUG A and LARSEN B, `The influence of pH on the rate of hydrolysis of acidic polysaccharides', Acta Chem Scand, 1966 20 1026±1034. SMIDSRéD O, HAUG A and LARSEN B, Òxidative-reductive depolymerization: a note on the comparison of degradation rates of different polymers by viscosity measurements', Carbohydr Res, 1967 5 482±485. Ê K-BRáK G, SMIDSRéD O, HEINTZ R, LANZA RP and ESPEVIK SOON-SHIONG P, OTTERLEI M, SKJA T, Àn immunologic basis for the fibrotic reaction to implanted microcapsules', Transplant Proc, 1991 23 758±759. SMIDSRéD O

Ê K-BRáK G, ESPEVIK SOON-SHIONG P, FELDMAN E, NELSON R, KOMTEBEDDE J, SMIDSRéD O, SKJA T, HEINTZ R and LEE M, `Successful reversal of spontaneous diabetes in dogs by intraperitoneal microencapsulated islets', Transplantation, 1992 54 769±774.

SOON-SHIONG P, FELDMAN E, NELSON R, HEINTS R, YAO Q, YAO T, ZHENG N, MERIDETH G, Ê K-BRáK G, ESPEVIK T, SMIDSRéD O and SANDFORD P, `Long-term reversal of SKJA

diabetes by the injection of immunoprotected islets', Proc Natl Acad Sci, 1993 90 5843±5847. STANFORD ECC, British patent #142, 1881. STEGINSKY CA, BEALE JM, FLOSS HG and MAYER RM, `Structural determination of alginic acid and the effects of calcium binding as determined by high-field NMR', Carbohydr Res, 1992 225 11±26. STEINER AB, `Manufacture of glycol alginates', U.S. Patent no. 2,426,215, 1947. STEINER AB and MCNEILLY WH, `High-stability glycol alginates and their manufacture', U.S. Patent no. 2,494,911, 1950. Ê K-BRáK G, `Distribution of uronate residues STOKKE BT, SMIDSRéD O, BRUHEIM P and SKJA in alginate chains in relation to alginate gelling properties', Macromolecules, 1991 24 4637±4645. Ê K-BRáK G, `Distribution of uronate STOKKE BT, SMIDSRéD O, ZANETTI F, STRAND W and SKJA residues in alginate chains in relation to gelling properties 2:Enrichment of -Dmannuronic acid and depletion of -L-guluronic acid in the sol fraction', Carbohydr Polym, 1993 21 39±46. STOKKE BT, DRAGET KI, SMIDSRéD O, YUGUCHI Y, URAKAWA H and KAJIWARA K, `Smallangle X-ray scattering and theological characterization of alginate gels. 1. Caalginate gels', Macromolecules, 2000 33 1853±1863. SUNDERLAND AM, DETTMAR PW and PEARSON JP, Àlginates inhibit pepsin activity in vitro; A justification for their use in gastro-oesophagal reflux disease (GORD)', Gastroenterology, 2000 118 347. SUTHERLAND IW, Surface carbohydrates of the prokaryotic cell, London, Academic Press, 1977, pp 22±96. TOFT K, GRASDALEN, H and SMIDSRéD O, `Synergistic gelation of alginates and pectins', ACS Symp Ser, 1986 310 117.

30 Inulin D. Meyer, Sensus, The Netherlands and J.-P. Blaauwhoed, Cosun Food Technology Centre, The Netherlands

Abstract: This chapter describes inulin and some of its application aspects in food. First the structure and industrial production are described followed by the technical properties relevant for food applications (e.g., solubility, viscosity, stability, interaction with hydrocolloids and gelling properties). Secondly, the nutritional and health benefits such as the low caloric value and the prebiotic properties are outlined, followed by some examples of the use of inulin in food applications. Emphasis is on those applications in which inulin is used as a fat and sugar replacer, to improve mouthfeel, etc. Finally, the regulatory status and some future developments are discussed. Key words: inulin, gelling properties, fat replacement, sugar replacement, interaction.

30.1

Introduction

Inulin has been well known for a long time. In 1804 Rose isolated a substance from Inula helenium (elecampane) that was later (in 1811) called inulin by Thomas (see Suzuki, 1993). These carbohydrates are synthesised in at least ten families of higher plants. They can be found in many economically important plants such as chicory, Jerusalem artichoke, onion, garlic, barley, rye and wheat. The data compiled in Table 30.1 show that inulins are an intrinsic ingredient of many of our common foodstuffs and as such these ingredients have been consumed for longer than we can remember. Inulin-containing crops were and are consumed not only from the crops mentioned in Table 30.1, which belong to a western type diet, but also in other countries, such as yacon tubers in South America and Japan, and murnong by Australian aboriginals. Jerusalem artichoke was consumed in Europe in the sixteenth century and in the early twentieth

830


Table 30.1

Inulin content of different crops

Source Banana (Musa cavendishii) Barley (Hordeum vulgare) Chicory (Cichorium intybus) Garlic (Allium sativum) Globe artichoke (Cynara scolymus) Jerusalem artichoke (Helianthus tuberosus) Leek (Allium ampeloprasum) Onion (Allium cepa) Wheat (Triticum aestivum)

Inulin content (% of fresh weight)

Range of DP

0.3±0.7 0.5±1.5 15±20 9±16 2±3 3±10 16±20 1±8 1±4

2±5 No data 2±60 2±50 2±250 2±50 No data 2±12 2±8

Based on data of van Loo et al. (1995) and Sensus (unpublished). DP: degree of polymerisation (see Fig. 30.1)

century inulin was already known as a carbohydrate suitable for diabetics, as it did not give rise to a glycemic response. Inulin is built up of 2±60 fructose units with one terminal glucose molecule (Fig. 30.1). Inulin is the generic name covering all -(2,1) fructans. In most cases inulins are a polydisperse mixture of fructan chains with a chain length (DP: degree of polymerisation) distribution dependent on the source (Table 30.1) and moment of harvesting. The term oligofructose or fructooligoaccharides is used for -(2,1) fructans with a DP up to about 10, and an

Fig. 30.1 Basic chemical structure of inulin GFn with terminal glucose residue (G: glucose; F: fructose; DP n 2; with n 1±60 for inulin from chicory).

Inulin

831

average DP of about 4. The topic of this chapter is mainly (long-chain) inulin with an average DP of at least 20.

30.2

Production process of inulin

In the early 1990s production of inulin as a food ingredient started in Europe. Industrial production of inulin almost exclusively uses chicory roots as raw material and is concentrated in the Netherlands and Belgium. Processing of chicory roots to produce inulin takes place under more or less the same conditions and with the same equipment as for the production of sucrose from sugar beet. As with sugar beet, processing also takes place in a campaign period from autumn to winter. After washing and slicing the roots, inulins are extracted with hot water. The so called diffusion juice can be transformed into a clear juice with liming and carbonation, similar to the purification of the diffusion juice in sugar beet processing. Alternatively, proteins and cell components can be precipitated and flocculated under slightly acidic conditions and separated off by filtration. Further refining by crystallisation at this stage as for white sugar production is not suitable for native inulin: the low solubility of long-chain inulin allows separation of this fraction by crystallisation, but the short-chain inulin fraction will remain in solution. For this reason separation techniques common for production of liquid sugars such as glucose are used in the refining of native inulin solutions. Removal of salts and most of the colour takes place by ion exchange. To prevent hydrolysis of inulin at low pH the whole process of ion exchange is carried out at low temperatures. After this step a slightly acidic, nearly fully demineralised inulin thin juice is obtained which is also low in colour. Finally the characteristic bitter taste of chicory is removed by activated carbon, which also removes any residual colour. The refined inulin juice is concentrated by evaporation and finally spray dried to obtain a powdered product. Spray drying takes place from completely dissolved inulin solutions resulting in amorphous powders with good solubility. Native inulin can be separated in short- and long-chain fractions by crystallisation. After crystallisation both long- and short-chain fractions can be spray dried to amorphous powders. This delivers types of inulin with a chain length distribution different from native inulin, which offer possibilities for different applications. The long-chain inulin with a DP ranging from about 10 to 60 is the main type of inulin discussed in this chapter.

30.3

Technical properties

30.3.1 Solubility Solubility in water is mostly dependent on the inulin chain length distribution. In Fig. 30.2, the maximum or direct solubility of native and long-chain inulin types is shown. As can be seen, the solubility increases with decreasing chain length.

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Fig. 30.2

Maximum solubility of native and long-chain inulin as a function of temperature. Data from Sensus (2003a).

Oligofructose is commercially available as syrup with a dry matter content of 75% which stays clear even at 5 ëC. Storage time and temperature are important factors for transparency of inulin solutions. Longer storage time might result in development of haze due to precipitation of long-chain inulins. In Table 30.2 the concentrations are given for obtaining a stable clear inulin solution in water for a long period of time. This is important, e.g., for the development of beverages which should stay clear for a longer period, or in products where precipitation may lead to a rough texture by the precipitated inulin particles. 30.3.2 Viscosity Solutions of native inulin in water are very low in viscosity, and also long-chain inulin exhibits only a slightly higher viscosity in solution compared to native inulin: e.g., a 20% solution in water has a viscosity of about 4.5 mPa s at 20 ëC. Table 30.2 Long-term solubility of inulin at different temperatures Type of inulin

Native inulin Long-chain inulin

Storage temperature 5 ëC

20 ëC

< 2.0% < 1.0%

< 2.5% < 1.5%

Inulin concentration in relation to inulin type and storage temperature resulting in a clear solution after 13 weeks of storage (Sensus, 2003a)

Inulin

833

30.3.3 Heat stability Inulin is stable to temperatures up to 140 ëC (when dissolved at near neutral pH) and can therefore be processed easily in most if not all food applications. It will break down at temperatures above 140 ëC. In powder form the heat stability is much higher. 30.3.4 Acid stability The -(2,1) glycosidic bond in inulin is susceptible to acid hydrolysis. The degree of hydrolysis depends on pH, food product composition (dry matter content) and time-temperature combination (during heat treatment or shelf-life). In general, hydrolysis will not occur at pH levels above 4.0. At pH levels below 4.0, hydrolysis may occur with the rate dependent on actual pH and temperature. For example, hydrolysis is not observed at temperature levels below 10 ëC at any pH between 3.0 and 7.5, but at pH 3 at 25 ëC about 10% hydrolysis takes place in 1 week. An example of inulin loss in acid solution with different inulin types is given in Fig. 30.3. 30.3.5 Inulin and hydrocolloids The function of hydrocolloids, which are also known as gums, thickeners, gelling agents, stabilisers, texturisers, is to thicken or gel aqueous systems. In doing so, they provide texture, body and mouthfeel to food products. Most of the hydrocolloids are high molecular weight polysaccharides. The water-binding property of these polymers is basically due to the fact that these macromolecules can form junction zones and so enclose large amounts of water. Because of this

Fig. 30.3 Inulin hydrolysis of different inulin types at pH 3.5 and 20 ëC. Inulin or FOS solutions (1%) were prepared in buffer and stored at pH 3.5 and 20 ëC. The inulin content (defined as inulin with DP > 2) was determined using Shodex GPC measurements.

834


high water binding effect, they can be used at low dosage levels. Proteins like gelatin also have the ability to form gels. Hydrocolloids can be divided in three groups: emulsifying/stabilising agents, thickening agents and gelling agents. Thickeners are used to thicken and increase viscosity of aqueous systems while gelling agents are able to convert water to a demouldable solid or gel. Inulin has different thickening and stabilising properties from hydrocolloids. The inulin molecule is much smaller and the water-binding ability is low compared to hydrocolloids. When concentrations exceed about 15%, inulin has the ability to form a gel or cream. Below this concentration, low viscous aqueous solutions are obtained, as mentioned above. Gel formation of inulin is also different compared to hydrocolloids. Inulin forms particle gels, similar to those formed by some starches (Harris and Day, 1993). Gel formation by hydrocolloids or the increase of viscosity with most hydrocolloids is due to interaction between the polymer chains. Due to the high number of hydroxyl groups present in inulin, it can be expected that inulin plays a role in hydrogen bonding in food systems, and that it may influence the solubility of other water-binding ingredients such as guar or xanthan gum, carrageenan, alginate, pectin, maltodextrin and starch. In other words, inulin takes part in the competition for water as solvent. Development of viscosity or gel formation will be changed as a result of this interference of inulin with the hydration of other hydrocolloids. This might result in a retardation of viscosity development, a higher viscosity, a more brittle gel (see Fig. 30.4 for carrageenan and inulin interaction) or a smoother product flow, and also syneresis can be reduced (Sensus, 2002). Research in model systems has shown that inulin in combination with hydrocolloids can influence the rheological behaviour of these ingredients and

Fig. 30.4 Effect of inulin on rheology of a carrageenan gel. Gel strength of a carrageenan gel with inulin or sucrose was measured in a Carrimed Rheometer. Based on data from Sensus (2002).

Inulin

Fig. 30.5

835

Effect of inulin on starch viscosity in relation with temperature.

additives. Inulin can provide a useful tool to affect rheology and textural perception of a food product. Although inulin does not act not like a thickener or gelling agent, in combination with hydrocolloids it influences the behaviour of these polysaccharides. In this way, inulin can optimise the rheological properties of products. The inulin product is highly polydisperse. It has significant influence (with its hydrogen bonding efficiency and consequent solubility (gel formation)) on various high water-binding ingredients such as guar gum, xanthan gum, carrageenans, alginates, pectins, locust bean gum, maltodextrin and starch. By adding inulin to thickeners the viscosity (decrease or increase) and flow characteristics of the aqueous solution can be affected. In Fig. 30.5, an example is shown how inulin may affect the viscosity of a starch solution at different temperatures. With high inulin concentrations viscosity is much lower than with lower concentrations. This may be due to the effect that the inulin network interferes with the starch network in such a way that viscosity is lowered. 30.3.6 Inulin as a gelling agent Preparation of an inulin gel is straightforward: inulin is dissolved in water and upon cooling the molecules start to precipitate and crystallise, and a gel is formed (Table 30.3). The rate of precipitation or crystallisation and consequently the size of the inulin particles depend on temperature, concentration and cooling process. The submicron-sized crystals go on to form aggregates which become interlinked to form a network. Within a few hours the free water is captured in

836

Handbook of hydrocolloids Table 30.3

Typical procedure for making an inulin gel

Preparation of a 25% (w/w) inulin gel 1. Dissolve 50 g inulin with DP about 25* in 150 g tap water. 2. Place the dispersion in a water bath at 72 ëC. 3. Heat the dispersion for 15 min while stirring. 4. Remove the solution from the water bath. 5. Place in a cold room, 5 ëC for at least 6 h. * E.g., FrutafitÕTEX as supplied by Sensus (the Netherlands)

the network of crystallised inulin particles, resulting in a gel structure. This gel has rheological properties very similar to those of fat and therefore inulin has been identified as an interesting ingredient for structuring in low- or zero-fat food products (Silva, 1996; Bot et al., 2004). 30.3.7 Parameters affecting gel characteristics The rheological features of an inulin gel can be influenced by the following parameters: · · · · ·

chain length distribution concentration preparation temperature amount of shear (Kim et al., 2001) use of seeding (Sensus, 2003b; Kim and Wang, 2001).

In Fig. 30.6, an example is given of the influence of concentration and inulin type on the firmness of a gel as measured with a Texture Analyser: long-chain inulins give a higher gel strength and for gel formation to occur with native inulin at least 20% of inulin is needed. With oligofructose no gels can be prepared at any concentration. As has been mentioned before, the formation of an inulin gel is based on the precipitation and crystallisation of inulin molecules. Research has shown that only the longer inulin molecules (DP > 10) participate in the gel structure and the smaller molecules remain dissolved (Hebette et al., 1998). It can be seen from Fig. 30.6, that inulin types with a higher average chain length, containing more long-chain inulin molecules, will form firmer inulin gels. An inulin gel belongs to the group of particle gels, and firmness increases with increasing concentration as shown in Fig. 30.6. Firmness of an inulin gel reaches its maximum when, during the manufacturing process, nearly all the inulin molecules become fully hydrated, with the exception of some seed crystals. These seed crystals are necessary to initiate the gelling process. Seed material other than inulin, such as maltodextrin or -(2,6)-linked fructans are not effective (Sensus, unpublished observations). The degree of hydration depends on the inulin concentration and temperature. The application of a shear treatment immediately after pasteurisation or during cooling will have a positive effect on increasing the firmness of an inulin

Inulin

837

Fig. 30.6 Gel strength in relation to concentration of native inulin (DP 9), long-chain inulin (DP 25) from chicory roots and inulin (DP 36) from Cynara scolymus. Inulin gels were prepared at the concentrations given on the X-axis by dissolving inulin at 85 ëC and cooling down overnight (see Table 30.3 for the procedure). Gel strength was measured with a Stevens Texture Analyser (Sensus, 2003b).

gel (Fig. 30.7). Maximum firmness can be achieved by using the so-called seeding process: an inulin solution is heated to a high temperature, so that all the inulin molecules are completely hydrated. Addition of inulin seed crystals during cooling, in combination with a shear treatment will result in a firm inulin gel with perfect sensory properties (Fig. 30.7).

Fig. 30.7

Effect of shear treatment and seeding on firmness of inulin gels.

838

30.4


Nutritional and health benefits

As the glycosidic bonds between the fructosyl residues are resistant to gastric acid and since humans lack the digestive enzymes for splitting these bonds, inulins and fructo oligosaccharides (FOS) pass unharmed from mouth to small intestine. After reaching the colon they are completely fermented by the bacteria present in that organ. This behaviour explains why inulins are dietary fibres. The products from this fermentation process (short chain fatty acids, SCFA; acetic, propionic and butyric acid) will be absorbed by the host and subsequently metabolised. This salvages part of the energy, but only about a third of the caloric content compared with digestible carbohydrates is liberated by this process. This explains why inulins and oligofructose are low caloric food ingredients with a caloric value of about 1.5 kcal/g (Roberfroid, 1999). The fermentation in the large intestine leads to a change in the composition of the colonic microbiota: specifically bifidobacteria (and lactobacilli) are favoured in their growth which leads to an increase in the number of these genera. This effect is observed in children (Kim et al., 2007) and in adults (e.g., Kolida et al., 2007). Concomitantly, often a decrease in Clostridium and Bacteroides is found. This effect on the bacterial composition is called the prebiotic effect of inulins. Gibson and Roberfroid (1995) coined this term and described this effect as follows: a prebiotic modulates the colonic bacterial flora beneficially by stimulating the growth of health bacteria (Bifidobacterium and Lactobacillus) and decreasing the number of potentially harmful species (e.g. clostridia). This fermentation of inulins may lead to a whole range of other physiological effects, some of them related to the fibre functions and others more specifically to the increase of health associated bacteria as described. It is beyond the scope of this overview to discuss all effects in detail. It suffices here to describe the different effects briefly, with a focus on the results from studies with human volunteers. The fibre effects include the contribution to an improved defecation pattern (Kleessen et al., 1997; den Hond et al., 2000) and a stool bulking effect (den Hond et al., 2000), but the bifidogenic effect may also play a role here. The fibre properties (the non-digestibility) are also relevant for the low glycemic response elicited by inulins and FOS. The glycemic response (GR) of inulins is very low: the purest commercially available inulin has a GR of 5, and native inulin a GR of about 14 (all relative to glucose set at 100; Meyer, 2007). This makes inulin a suitable ingredient for food for diabetics, and for the development of low GR food products (Meyer, 2007). The fermentation of inulins may lead to a locally lowered pH thereby increasing the solubility of various salts. This improves their availability for absorption and it has been found that calcium and magnesium absorption in humans increases following inulin or FOS consumption (Meyer and StasseWolthuis, 2006). This may have a positive effect on bone density as has been found in various animal trials (e.g., Scholz-Ahrens et al., 2002) and in humans volunteers (Abrams et al., 2005).

Inulin

839

Another effect attributed to inulins is the lowering of serum lipids, thereby possibly contributing positively to heart health by lowering the risk for cardiovascular disease. Some studies showed a lowering of triglycerides (e.g., Causey et al., 2000) or cholesterol (e.g., Davidson et al., 1998), but others showed no effect (e.g., Pedersen et al., 1997). It appears that especially in dyslipidemic volunteers inulin consumption may lower serum lipids (Beylot, 2005). Recent data show that inulin can also have a positive effect on satiety feeling and energy intake. In people consuming inulin as a fat replacer in sausages, energy intake over the day is diminished (Archer et al., 2004) and similar data were reported by Cani et al. (2006) for volunteers consuming oligofructose. Inulins can also affect the immune system, possibly directly, but also through the increase in bifidobacteria and lactobacilli. Most of the effects described so far originate from experimental animal trials, and only a few examples from human studies have been published. These include a non-significant lowering of the incurrence of traveller's diarrhoea with FOS consumption (Cummings et al., 2001) and a reduced inflammation of the mucosa of the ileal reservoir in ileal pouch-anal anastomosis patients (Welters et al., 2002). There is also evidence to suggest that inulin may lower the risk for colon cancer. Especially in experimental animal trials with chemically induced colon cancer, positive results have been obtained showing that with inulin consumption, and especially in combination with probiotics, the occurrence of colon cancer can be prevented (e.g., Femia et al., 2002). It has also been reported that certain biomarkers for colon cancer risk in humans can be affected such that this risk may be lowered by such inulin-based synbiotics (Rafter et al., 2007).

30.5

Applications

The rheological and sensory characteristics of inulin gels make them an excellent fat replacer in a wide range of foods (Silva, 1996). An overview is presented in Table 30.4, with emphasis on those applications for long-chain and native inulin in which the features discussed above play a role. For an overview of applications of all types of inulin, including oligofructose, we refer to Meyer et al. (2007). Generally speaking inulins are applied in the following markets: dairy, bakery, beverages, cereals and cereal bars, infant nutrition, confectionery, ice cream, but also in feed and pet food (see Verdonk et al., 2005 for a review of the latter applications). A positive influence is observed in the following applications by adding inulin. With thickeners (xanthan, guar gum and pectins) stabilised beverage systems become more homogeneous when inulin is added. Due to H-binding influences, inulin provides the necessary flow properties and physiological effects. This is also particularly effective in gum-based fat-free dressings and sauce applications where fat-like flow and mouthfeel are of primary importance.

840


Table 30.4

Overview of applications of native and long-chain inulins

Application

Chain Dosage Replacement lengtha (%) L/N/S Fat Sugar

Technological functionality

Dairy products Yoghurt Milk drink Breakfast drink Mousse Dairy spread

L/N N N L/N L

2±4 3±5 2±5 3±20 4±10

Mouthfeel Mouthfeel Mouthfeel Foam stabilisation, mouthfeel Texturiser, syneresis prevention

Bakery products Bread Hamburger bun Short dough biscuit

L/N L/N N/S

3±10 3±7 2±8

Maria biscuit

N/S

3±10

+ + + + +

+

+

+ +

Aerated cake filling N

5±15

+

Biscuit filling Microwave pizza Wafer

N L/N N

5±20 1±3 1±3

+

Miscellaneous Fat spread Extruded cereals Dressing Chocolate Meat products Tablets Pasta filling

L L/N L/N L/N L/N N L/N

4±20 3±20 2±10 3±20 2±7 5±40 2±7

+ + + +

+ +

Flour replacement Flour replacement Crispiness, gluten softening, sweetness Crispiness, gluten softening, sweetness Texturiser, foam stabiliser, mouthfeel Bulking agent Crispiness enhancement Crispiness enhancement Texturiser Crispiness; bowl life Mouthfeel Bulking agent Texturiser, mouthfeel Direct compressible excipient Texturiser, mouthfeel

a Chain length: L: long-chain inulin (average DP 20±25); N: native inulin (average DP 9±11); S; oligofructose with average DP about 4. Based on data from Sensus (2005) and Franck (2000).

The viscosity of starch is influenced because of the greater affinity for water of inulin compared to starch. A smoother flow is obtained which can be a benefit in starch-based sauces. A creamier mouthfeel is also obtained when inulin is added to dairy products due to interactions with the dairy components, whey proteins and caseinate (Kip et al., 2006). This effect is even stronger when combined with -carrageenan as seen in flans and instant mousses. In dairy- and low-fat spreads, stabilised by gelatin or maltodextrin, the spreadability and mouthfeel is improved when inulin is added and a more fat-like structure is obtained. 30.5.1 Fat spreads and dairy spreads Addition of 7.5% native inulin to fat spreads with 20±40% fat (w/o emulsions) results in a product with a good structure and a perfect taste. The excellent

Inulin

841

spreadability and mouthfeel make it a perfect, low-fat substitute for sandwich margarines with 80% fat. An inulin gel based on 20% long-chain inulin is the base for a very low-fat spread (o/w emulsions) with no more than 5% fat and for dairy spreads like cream and cheese spreads. 30.5.2 Low-fat mayonnaise/dressing Traditional problems with low-fat or no fat mayonnaise and dressings are a lumpy texture with an acidic taste and a dry and sour aftertaste. With the addition of inulin (5%), a stable low-fat mayonnaise or dressing with good flow properties is achieved. Furthermore, inulin is capable of masking the acidic/sour taste. 30.5.3 Low-fat yoghurt The preparation of low-fat, no fat yoghurt is done by starting with skimmed milk. To obtain the same mouthfeel as traditional yoghurt, inulin is added. By adding inulin the viscosity of the yoghurt is increased and a similar mouthfeel to normal yoghurt is obtained. Research has shown that especially airiness in lowfat yoghurts is increased by the addition of inulin. The increase of this texture attribute contributes significantly to the increased creaminess (Fig. 30.8; Kip et al., 2006). A problem which occurs in other fat-free yoghurts is that the taste is more acidic. Inulin is capable of masking this effect. 30.5.4 Low-fat and low-sugar ice cream Fat in a premium quality ice cream contributes to sensory properties (such as mouthfeel, melting behaviour and creaminess) and physical properties (such as hardness and stability). The role of sugar in ice cream is very much related to

Fig. 30.8 Effect of long-chain inulin on creaminess of skimmed yoghurt. Data from Kip et al. (2003).

842


texture, hardness and stability, as well as taste and sweetness. Removing fat and sugar from ice cream will thus affect taste, texture and mouthfeel of the final product. Inulin and oligofructose can return the desired sensory attributes to low-fat and low-sugar ice cream products (Schaller-Povolny and Smith, 1999) with inulin contributing to a creamy mouthfeel, homogeneous melting and improved heat shock stability, and oligofructose providing a sweet taste, scoopability, and synergy with high intensity sweeteners, helping mask the aftertaste. Both ingredients help to maintain small ice cream crystals after heat shock, which is necessary for good mouthfeel and improves the shelf-life. Inulin and oligofructose offer excellent opportunities for sugar and fat replacement in ice creams. High quality products can be obtained in terms of the microstructure, sensory characteristics, melting properties and heat shock stability (McDevitt-Pugh and Peters, 2005). 30.5.5 Low-fat cake Partial replacement of the pastry margarine by an inulin gel results in a fatreduced cake with perfect sensory properties and a long shelf-life. Research has also shown that the combination of inulin with maltodextrin results in cakes with more volume. 30.5.6 Fillings The creamy structure of an inulin gel makes it a perfect base for fillings which allows biscuits to be made with a filling in which 25% of the fat was replaced. 30.5.7 Wafers The most important characteristic of wafers is their crispness, because this influences the perception of freshness. They should not lose their crispness during storage and preferably they should also stay crisp when they are filled with ice cream and fruit or as a sandwich wafer. The final wafer product becomes crisper when inulin is used. The crispness of a product can be characterised by the sound during breaking of the product. The degree of crispness depends on several aspects. The density of the product has a major influence; the lower the density the easier the wafer breaks. At higher moisture contents the wafer will also not be crisp. Another aspect is the absorption profile of the starch used. The absorption profile is characterised by the relation between the water content and the water activity (Aw). A product stays crisp until a water activity of 0.1±0.2. When the absorption profile line is steep (see Fig. 30.9, curve 1) the product is crisp only until a water content of approximately 3%. With a less steep absorption profile the product stays crisp until a higher water content (Fig. 30.9, curve 2). Inulin is able to bind water, so there will be less free water in the

Inulin

Fig. 30.9

843

Absorption profiles.

product (see also Schaller-Povolny et al., 2000). This means that a wafer with inulin can contain more moisture and stay crisp. 30.5.8 Low-fat hazelnut spread Commercial hazelnut spreads are fat-based products. Dry ingredients are milled and finely dispersed in the fat phase to achieve the right mouthfeel. A structure based on 12% native inulin with addition of sugars, cocoa powder, milk proteins and hazelnut paste makes it possible to produce a delicious low-fat (water continuous) hazelnut spread. Compared with the conventional product a calorie reduction of 45% can be achieved.

30.6

Regulatory status

Regulations differ from country to country. Because inulin is part of our daily diet (Table 30.1), it is considered as a food ingredient, so it has no E-number in the EU (it is not an additive) and it can be used ad libitum in all food categories. Inulin has the status of dietary fibre in almost every country. As described above inulin can be used as a fat replacer and this creates the possibility to make nutrition claims based on the reduced fat or energy content of the food product. Table 30.5 shows such claims and conditions applying to them from EU 1924/2006, the latest legislation in the 27 member states of the EU (European Commission, 2006). As inulins are also a dietary fibre for labelling purposes, the fibre claims as mentioned in the Table 30.5 are equally applicable. Also in the USA nutrition claims are possible, but in contrast to the EU where the percentage in the food is the basis, the concentration of inulin per serving size is the basis in the USA for making claims. As an example, a `low fat' claim is allowed when the fat content is less than 3 g, whereas a `fat free' claim requires less than 0.5 per serving (see FDA, 1999). Dietary fibre claims, such as èxcellent source of fibre', are based on a certain percentage of the reference daily intake of 25 g/d (FDA, 1999).

844


Table 30.5

Overview of nutrition claims from EU 1924/2006

Claim

Conditions

Low energy

Less than 40 cal (170 kJ)/100 g for solids, or 20 kcal (80 kJ)/ 100 ml for liquids. For table-top sweeteners a limit of 4 kcal (17 kJ)/portion applies

Energy-reduced

Energy value reduced by at least 30% (with an indication of the characteristic(s) which make(s) the food reduced in energy)

Energy-free

Less than 4 kcal or 17 kJ per 100 ml, for table-top sweeteners less than 0.4 kcal (1.7 kJ) per portion

Low fat

Less than 3 g of fat per 100 g for solids, or 1.5 g of fat per 100 ml for liquids (1.8 g per 100 ml for semi-skimmed milk)

Fat-free

Less than 0.5 g per 100 g or 100 ml (X% fat-free is prohibited)

Source of fibre

At least 3 g of fibre per 100 g (or 1.5 g per 100 kcal)

High fibre

At least 6 g of fibre per 100 g (or 3 g per 100 kcal)

Reduced [ingredient]

Reduction of at least 30% compared to a similar product

Increased [ingredient]

Increase of at least 30% compared to a similar product

Light/lite

Conditions as for `reduced' and an indication of the charcteristic(s) which make(s) the food light/lite

For further details, see European Commission (2006).

Health claims based on inulin, such as based on the prebiotic or other effects described above, are also regulated in EU 1924/2006. A list of approved health claims describing the effect of an ingredient on a physiological function will be published at the latest on 31 January 2010. These Article 13 claims will be based on generally accepted scientific evidence. It seems very likely that (some of) the health effects of inulin will be on this list; for instance, a bifidogenic gut health claim is already approved in France (AFSSA, 2005) and the Netherlands (Rombouts et al., 2002). For so-called Article 14 claims (risk of disease reduction claims or claims aimed at growth and development of children) pre-market approval is required. The procedure to obtain such approval is described in EU 1924/2006 (European Commission, 2006). In the USA, so-called structure-function claims, which describe the effect of an ingredient on the structure or physiological function, do not require premarket approval. Care should be taken to avoid mentioning a disease in this type of claim, and that the necessary evidence is available, for instance to claim the effect of inulin on calcium absorption.

Inulin

30.7

845

Future trends

In view of the oncoming obesity pandemic, it is to be anticipated that development of low caloric food products with an optimal taste and texture will continue at an increasing speed. Inulin on its own or in combination may be an important ingredient for these developments as it is low caloric and provides numerous health benefits, some of which are clearly relevant for the trends described, in particular the ability to improve satiety. Also the interactions with hydrocolloids are important as these may contribute to proper food texture and flavour release in a variety of products. In connection with this, it might be interesting to look also for new tools to investigate these aspects; instead of focusing on the bulk rheological properties of the product, the interaction of the product in the mouth, with palate and tongue, might provide more clues to the assessment of texture and its sensory attributes, such as creaminess (e.g., Dresselhuis et al., 2007). This means that future developments are to be aimed at providing more insight into the mechanisms behind the interactions, which will contribute to building better food products. By including inulin the health properties of such products might be further enhanced. Further research to provide the scientific evidence for the health benefits of inulin will create the possibility of making health claims on inulin-containing foods to convey a credible message to the consumer.

30.8

Acknowledgements

The work of following collaborators from Cosun Food Technology Centre is gratefully acknowledged: S. Bink and B. Walraven for isolating the inulin from Cynara scolymus, P. Kip and J. de Wolf (now with Givaudan) for their research on low-fat yoghurt.

30.9

References

and (2005) A combination of prebiotic short- and long-chain inulin-type fructans enhances calcium absorption and bone mineralization in young adolescents. Am. J. Clin. Nutr. 82: 471±476. AFSSA (2005) Avis de L'Agence FrancËaise de securiteÂ sanitaire des aliments relatif aÁ l'eÂvaluation des alleÂgations nutritionnelles concernant l'effet bifidogeÁne de l'inuline sur la flore intestinal humaine. AFSSA, Maisons-Alfort cedex, France. ARCHER, B.J., JOHNSON, S.K., DEVEREUX, H.M. and BAXTER, A.L. (2004) Effect of fat replacement by inulin or lupin-kernel fibre on sausage patty acceptability, postmeal perceptions of satiety and food intake in men. Br. J. Nutr. 91: 591±599. BEYLOT, M. (2005) Effects of inulin-type fructans on lipid metabolism in man and in animal models. Br. J. Nutr. 93: S163±S168. ABRAMS, S.A., GRIFFIN, I.J., HAWTHORNE, K.M., LIANG, L., GUNN, S.K., DARLINGTON, G. ELLIS, K.J.

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and AGTEROF, W.G.M. (2004) Influence of crystallisation conditions on the large deformation rheology of inulin gels. Food Hydrocolloids 18: 547±556. CANI, P.D., JOLY, E., HORSMANS, Y. and DELZENNE, N.M. (2006) Oligofructose promotes satiety in healthy human: a pilot study. Eur. J. Clin. Nutr. 60: 567±572. CAUSEY, J.L., FEIRTAG, J.M., GALLAHER, D.D., TUNGLAND, B.C. and SLAVIN, J.L. (2000) Effects of dietary inulin on serum lipids, blood glucose and the gastrointestinal environment in hypercholesterolemic men. Nutr. Res. 20: 191±201. CUMMINGS, J.H., CHRISTIE, S. and COLE, T.J. (2001) A study of fructo oligosaccharides in the prevention of travellers' diarrhoea. Aliment. Pharmacol. Therapeut. 15: 1139± 1145. DAVIDSON, M.H., MAKI, K.C., SYNECKI, C., TORRI, S.A. and DRENNAN, K.B. (1998) Effects of dietary inulin on serum lipids in men and women with hypercholesterolemia. Nutr. Res. 18: 503±517. DEN HOND, E., GEYPENS, B. and GHOOS, Y. (2000) Effect of high performance chicory inulin on constipation. Nutr. Res. 20: 731±736. DRESSELHUIS, D.M., HOOG, E.H.A. DE, COHEN STUART, M.A. and AKEN, G.A. VAN (2007). Tribology as a tool to study emulsion behaviour in the mouth. In: Food Colloids: Self-assembly and Material Science (Dickinson, E. and Leser, M.E., eds.). Springer Verlag, Berlin, pp. 451±461. EUROPEAN COMMISSION (2006) Regulation for nutrition and health claims made on Foods (EU 1924/2006), available at: http://eur-lex.europa.eu/LexUriServ/site/en/oj/2007/ l_012/l_01220070118en00030018.pdf. FDA (1999) Center for Food Safety and Applied Nutrition. A Food Labeling Guide, available at: http://www.cfsan.fda.gov/~dms/foodlab.html. BOT, A., ERLE, U., VREEKER, R.

FEMIA, A P., LUCERI, C., DOLARA, P., GIANNINI, A., BIGGERI, A., SALVADORI, M. CLUNE, Y.

COLLINS, K.J., PAGLIERANI, M. and CADERNI, G. (2002) Antitumorigenic activity of the prebiotic inulin enriched with oligofructose in combination with the probiotics Lactobacillus rhamnosus and Bifidobacterium lactis on azoxymethane-induced colon carcinogenesis in rats. Carcinogenesis 23: 1953±1960. FRANCK, A. (2000) Prebiotics and Probiotics Ingredients Handbook, Leatherhead Food Publishing, Reading. GIBSON, G.R. and ROBERFROID, M.R. (1995) Dietary modulation of the human colonic microbiota: introducing the concept of prebiotics. J. Nutr. 125: 1401±1412. HARRIS, D.W. and DAY, G.A. (1993) Structure versus functional relationships of a new starch-based fat replacer. Starch/StaÈrke 45: 221±226. HEBETTE, C.L.M., DELCOUR, J.A., KOCH, M.H.J., BOOTEN, K., KLEPPINGER, R., MISCHENKO, N. and REYNAERS, H. (1998) Complex melting of semi-crystalline chicory (Cichorium intybus L.) root inulin. Carbohydr. Res. 310: 65±75. KIM, S.-H, LEE, D.H. and MEYER, D. (2007) Supplementation of baby formula with native inulin has a prebiotic effect in formula-fed babies. Asia Pac. J. Clin. Nutr. 16: 172±177. KIM, Y. and WANG, S.S. (2001) Kinetic study of thermally induced inulin gel. J. Food Sci. 66: 991±997. KIM, Y., FAQIH, M.N. and WANG, S.S. (2001) Factors affecting gel formation of inulin. Carbohydr. Polym. 46: 135±145. KIP, P., PETERS, B. and MEYER, D. (2003) Improving mouth feel and texture of stirred yoghurt by the addition of inulin. Abstract P37 3rd NIZO Dairy Conference. Dynamics of texture, process and perception (11±13 June 2003, Papendal, the Netherlands).

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and JELLEMA, R.H. (2006) Inulins improve sensoric and textural properties of low fat yoghurts. Int. Dairy J. 16 (9): 1098±1103. KLEESSEN, B., SYKURA, B., ZUNFT, H. J. and BLAUT, M. (1997) Effects of inulin and lactose on fecal microflora, microbial activity, and bowel habit in elderly constipated persons. Am. J. Clin. Nutr. 65: 1397±1402. KOLIDA, S., MEYER, D. and GIBSON, G.R. (2007) A double-blind placebo-controlled study to establish the bifidogenic dosage of inulin in healthy humans. Eur. J. Clin. Nutr. 61: 1189±1195. MCDEVITT-PUGH, M. and PETERS, B. (2005) Weight management supported by tasty inulinbased products. AgroFood Ind. Hi-tech 16: 36±37. MEYER, D. (2007) Inulins for product development of low GI products to support weight management. In: Dietary Fibre Components and Functions (H. Salovaara, F. Gates and M. Tenkanen, eds). Wageningen Academic Publishers, Wageningen, the Netherlands, pp. 257±270. MEYER, D. and STASSE-WOLTHUIS, M. (2006) Inulin and bone health. Curr. Top. Nutraceut. Res. 4: 211±226. MEYER, P.D., WOLF, J. DE and OLIVIER, P. (2007) Inulin und Fructooligosaccharide. In: Handbuch SuÈûungsmittel (K. Rosenplenter and U. NoÈhle, eds). Behr's Verlag, Hamburg, pp. 155±193. È M, B. and AMELSVOORT, J.M.M. VAN (1997) The effect of ingestion PEDERSEN, A., SANDSTRO of inulin on blood lipids and gastrointestinal symptoms in healthy females. Br. J. Nutr. 78: 215±222. KIP, P., MEYER, D.

RAFTER, J., BENNETT, M., CADERNI, G., CLUNE, Y., HUGHES, R., KARLSSON, P.C., KLINDER, A., O'RIORDAN, M., O'SULLIVAN, G.C., POOL-ZOBEL, B., RECHKEMMER, G., ROLLER, M.,

and COLLINS, J.K. (2007) Dietary synbiotics reduce cancer risk factors in polypectomized and colon cancer patients. Am. J. Clin. Nutr. 85: 488±496. ROBERFROID, M.B. (1999) Caloric value of inulin and oligofructose. J. Nutr. S1436±S1437. ROMBOUTS, F.M., BRANDT, P.A. VAN DEN, NAGENGAST, F.M. and SCHAAFSMA, G.J. (2002) Assessment report according to the Code of Practice for assessing the scientific evidence for health benefits. Netherlands Nutrition Centre, The Hague, available at: (http://www.voedingscentrum.nl/NR/rdonlyres/85938396-FFD6-44B0-8143769E3B25A14C/0/beoordelingsrapport_vitaalbrood_florapdf.pdf). SCHALLER-POVOLNY, L.A. and SMITH, D.E. (1999) Sensory attributes and storage life of reduced fat ice cream as related to inulin content. J. Food Sci. 64: 555±559. SCHALLER-POVOLNY, L., SMITH, D.E. and LABUZA, T P. (2000) Effect of water content and molecular weight on the moisture isotherms and glass transition properties of inulin. Int. J. Food Prop. 3: 173±192. SCHOLZ-AHRENS, K.E., ACIL, Y. and SCHREZENMEIR, J. (2002) Effect of oligofructose or dietary calcium on repeated calcium and phosphorus balances, bone mineralization and trabecular structure in ovariectomized rats. Br. J. Nutr. 88: 365±378. Õ SENSUS (2002) Frutafit inulin interactions with hydrocolloids. Brochure. Õ Õ SENSUS (2003a) Stability of Frutafit and Frutalose inulin/FOS in beverage applications. Brochure. Õ SENSUS (2003b) Frutafit inulin gels. Preparation and opportunities. Brochure. Õ Õ SENSUS (2005) The Frutafit and Frutalose product ranges, Brochure. SILVA, R.F. (1996) Use of inulin as a natural texture modifier. Cereal Foods World 41: 792±794. SUZUKI, M. (1993) History of fructan research: Rose to Edelman. In: Science and ROWLAND, I., SALVADORI, M., THIJS, H., LOO, J. VAN, WATZL, B.

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Technology of Fructans (M. Suzuki and N.J. Chatterton, eds). CRC Press, Boca Raton, FL, pp. 22±39. VAN LOO, J., COUSSEMENT, P., LEENHEER. L. DE, HOEBREGS, H. and SMITS, G. (1995) On the presence of inulin and oligofructose as natural ingredients in the western diet. Crit. Rev. Food Sci. Nutr. 35: 535±552. VERDONK, J.M.A.J., SHIM, S,B., LEEUWEN, P. VAN and VERSTEGEN, M.W.A. (2005) Application of inulin-type fructans in animal feed and pet food. Br. J. Nutr. 93: S12±S138. WELTERS, C.F.M., HEINEMAN, E., THUNNISSEN, F.B.J.M., BOGAARD. A.E.J.M VAN DEN, SOETERS,

and BAETEN, C.G.M.I. (2002) Effect of dietary inulin supplementation on inflammation of pouch mucosa in patients with an ileal pouch-anal anastomosis. Dis. Colon Rectum 45: 621±627. P.B.

31 Chitin and chitosan hydrogels R. A. A. Muzzarelli, Muzzarelli Consulting, Italy and University of Ancona, Italy and C. Muzzarelli, University of Ancona, Italy

Abstract: A large number of hydrogels of modified chitins and chitosans have become available during the last few years for a variety of applications in research and technology. The simplest example of hydrogel formation is the treatment of a chitosan acetate solution with carbodiimide to restore acetamido groups. A large variety of substituted amides have been obtained by reacting chitosan with anhydrides and acyl chlorides. Hydrogels are formed by polyelectrolyte complexation as in the case of chitosan salts treated with pentasodium tripolyphosphate or other polymeric anionic substances including DNA, polysaccharides, proteins, inorganic or synthetic polymers, but also according to more sophisticated approaches such as the use of tyrosinase, laccase and other enzymes, or crosslinking agents like glycidoxypropyltrimethoxysilane. While the controlled and targeted delivery of drugs is obtained today with chitosan-based vectors capable of forming safe and bioresorbable hydrogels, on the other hand intelligent articles and sensors are currently manufactured from chitosan hydrogels as well. The biochemical significance of chitin and chitosan in the food area is based on the role that chitosan gels play when interacting with bile salts (cholesterol lowering, overweight control), and with intestinal bacteria (control over bacterial flora, and enhanced absorption). The preservation of fruit and vegetables from microbial spoilage with the aid of chitosan gels and films is becoming more and more important, because today chitosan is recognised as safe and it is approved for human consumption in many countries. Key words: chitin, chitosan, drug delivery, nutritional value, cholesterol lowering, antimicrobial activity, polyelectrolytes.

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31.1


Introduction

Hydrogels, composed of water-soluble or swelling macromolecules, exhibit high water content, biocompatibility and desirable mechanical properties; the xerogels resulting after dehydration exhibit large specific surface area, and a network suitable for the incorporation of biomolecules. Present and future microgel applications require control over properties that include novel functionality, controlled particle size and tunable biodegradability. Major advances in the area of microgel/nanogel particles deal with drug delivery carriers for biological and biomedical applications (Oh et al., 2008), but food applications have long testified to a great deal of interest in natural and semisynthetic hydrogels. This chapter provides information on some chitin- and chitosan-based hydrogels suitable for applications in the food and welfare areas. Among polysaccharides, chitin is known for a large variety of hydrogels that can be obtained through chemical or enzymatic modification. Chitin, (1-4)linked 2-acetamido-2-deoxy- -D-glucan, is widely distributed among invertebrates. It is found as -chitin in the calyces of hydrozoa, the egg shells of nematodes and rotifers, the radulae of chitons and limpets (Shaw et al., 2008) and the cuticles of arthropods; sponges possess chitin as a component of their skeletons (Ehrlich et al., 2007). -chitin is present in the shells of brachiopods and molluscs, the cuttlefish bone, the squid pen, and pogonophora tubes. Chitin is found in exoskeletons, peritrophic membranes and cocoons of insects. The chitin in the fungal walls varies in crystallinity, degree of covalent bonding to other wall components, mainly glucans, and its degree of acetylation. Basic information on chitin and chitosan is available in books, encyclopedias and review articles (Enescu and Olteanu, 2008; Goosen, 1996; Kumar et al., 2004; JolleÁs and Muzzarelli, 1999; Kurita, 2006; Mano et al., 2007; Morimoto et al., 2002; Mourya and Inamdar, 2008; Muzzarelli, 1977; 1985a,b; 1993; 1996a,b; 2000; 2001; 2005; 2009a,b; Muzzarelli et al., 1986; Rinaudo, 2006a,b; RuelGariepy and Leroux, 2006; Terbojevich and Muzzarelli, 2000; Varghese and Elisseeff, 2006; Vinsova and Vavrikova, 2008; Yalpani, 1988). Today, chitins and chitosans of various grades are commercially available in large quantities from producers all over the world. Chitin isolates differ from each other in many respects, including degree of acetylation, defined as the molar fraction of GlcNAc, typically close to 0.90; elemental analysis, with nitrogen content typically close to 7%, and N/C ratio 0.146 for fully acetylated chitin; molecular size and polydispersity. The average molecular weight of chitin in vivo is probably in the order of one million Da, but chitin isolates have lower values due to partial random depolymerisation occurring during the chemical treatments and depigmentation steps. The presence of a substantial quantity of nitrogen is a point of difference from other abundant polysaccharides: the fact that chitin contains four elements instead of three is often ignored when chitin is compared to cellulose. Chitosans are a family of deacetylated chitins. In general, chitosans have nitrogen content higher than 7% and degree of acetylation lower than 0.40. The

Chitin and chitosan hydrogels

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removal of the acetyl group from chitin is a harsh treatment usually performed with concentrated NaOH. Protection from oxygen, with a nitrogen purge or by addition of sodium borohydride to the alkali solution, is necessary in order to avoid undesirable reactions such as depolymerisation and generation of reactive species. Commercial chitosans may contain insoluble highly acetylated fractions that come from the core of the granules submitted to heterogeneous deacetylation. The acetyl groups in the acid-soluble fractions are randomly distributed, whilst the insoluble fractions contain relatively long sequences of acetylated units. Chitin and chitosan are not present in the human tissues, but acetylglucosamine and chitobiose are found in glycoproteins and glycosaminoglycans. Since chitosan is biodegradable, non-toxic, non-immunogenic and biocompatible in animal tissues, much research has been directed toward its use in medical applications such as drug delivery, artificial skin and blood anticoagulants.

31.2

Chitosan chemistry

31.2.1 Chemical structure and molecular characterisation The degree of acetylation for commercial samples is about 0.20. Experimental chitosan samples can be deacetylated almost completely, giving polyglucosamine. The evaluation of the degree of acetylation can be carried out by a number of techniques, depending on the amount of acetylated units. A total of 22 analytical methods were proposed for the determination of the degree of acetylation (Hein et al., 2008), including one based on UV spectrophotometry (Muzzarelli and Rocchetti, 1985; Wu and Zivanovic, 2008). High-resolution 1H and 13C NMR spectroscopy can provide information not only on the degree of acetylation in solution and solid state, but also on the sequence structure: in particular, random and block arrangements of GlcNAc and GlcN units are detected. In order to evaluate the average molecular weight of chitosan, viscometric and gel permeation chromatographic techniques are used. In contrast to the static light scattering method, which gives absolute values for molecular weight, the above techniques are empirically related to chain length and require calibration curves. On the other hand, light scattering measurements are difficult to perform and sometimes the data are difficult to interpret, in the presence of aggregation and association. In summary, the molecular weight characterisation of chitosan remain problematic: probably the viscometric method, easy and rapid to perform, and not greatly affected by the presence of negligible amounts of very high molecular weight polymer, is the best choice, provided that the Mark±Houwink±Sakurada equation is correctly used with sets of values as reported in the literature (Kasaai, 2007), for various aqueous salt systems in which the viscometric measurements are performed. Average molecular weight for chitosans can reach values of 500 kDa or more. Gel permeation chromatography methods are available to evaluate the molecular weight distribution of chitosan samples: calibration is performed by

852


means of commercial standards (pullulan, for instance) or chitosan samples (Terbojevich et al., 1993). A good improvement is obtained by using a lowangle laser light scattering instrument as an on-line detector (Beri et al., 1993). Samples of chitosan with polydispersity index ca. 1.2±1.5 were obtained by preparative gel permeation chromatography; no variation of the degree of acetylation related to molecular weight was found. Attempts to perform molecular weight fractionation of commercial chitosans by selective precipitation with ethanol or acetone from aqueous solutions or by ion exchange were only partially successful. The reasons for this are depolymerisation of chitosan chains during the experiments, and incomplete recovery of the polymeric material from the chromatographic column. Depolymerisation of chitosan Chitosan chains can be chemically depolymerised by cleavage of the glycosidic bond catalysed by acids and, to a lesser extent, by bases. The rate of depolymerisation depends on the type and the concentration of the acid and on the temperature: the extent of depolymerisation can be calculated following the equations reported in the literature (Terbojevich et al., 1992). In the presence of nitrous acid, nitrosating species attack the glucosamine, but not the N-acetylglucosamine moieties and a 2,5-anhydro-D-mannose unit is formed at the reducing end of the cleaved polymer. As a consequence, after the depolymerisation, the samples have not only lower molecular weight than starting chitosans, but also different composition and sequence arrangement. Hydrogen peroxide can also be conveniently used to depolymerise chitosan. As for enzymatic depolymerisation, many commercial enzyme preparations exert hydrolytic activity on chitosans, that appear to be unexpectedly vulnerable to a range of hydrolases: several proteases such as pepsin, bromelain, ficin and pancreatin display lytic activities towards chitosans that surpass those of chitinases and lysozyme. Cellulases, hemicellulases, lipases, proteases and pectinases are also effective (Yalpani and Pantaleone, 1994). This unspecific activity is possibly due to the simplicity of the enzyme±substrate complex formation. Almost all the cellulases produced by different kinds of micro-organisms can degrade chitosan to chitooligomers, thus they advantageously replace chitinases that are very expensive. The existence of bifunctional enzymes with cellulase and chitosanase activity is one of the reasons for cellulase efficacy on chitosan hydrolysis (Xia et al., 2008). In order to prevent the browning of the chitooligomers prepared via enzymatic hydrolysis, the chitooligomers were reduced with potassium borohydride to improve their chemical stability. The reduced chitooligomers had no oral acute toxicity, and they had almost the same biological significance in mice when injected intraperitoneally as the fresh chitooligomers (Qin et al., 2008).


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31.2.2 Chitosan production The chemical composition and the distribution of different units along the chitosan chains are strictly related to the polymer preparation; therefore there is an important relationship between production and properties of chitosans, both in solution and in the solid state. The deacetylation of chitin is studied as a function of NaOH concentration, reaction time and temperature as determined by alkalimetric titration. Deacetylation is performed by traditional heating or under microwave irradiation. The maximum degree of deacetylation (98%) can be obtained after 30 min of thermal heating at 135 ëC in 50 wt% NaOH solution (Leonhardt et al., 2008). The shells of the brine shrimp Artemia urmiana are a rich source of chitin (29.3±34.5% of the shell dry weight). Artemia chitosan exhibited a medium molecular weight (450±570 kDa), regular degree of deacetylation (67±74%) and relatively low viscosity (29±91 centiposes). The physico-chemical characteristics (e.g., ash, nitrogen and molecular weight) and functional properties (e.g., water-binding capacity and antibacterial activity) of the prepared Artemia chitosans were enhanced, compared to crab control and commercial samples (Tajik et al., 2008). Chitosan of fungal origin in the molecular range 5±10 kDa was firstly prepared directly from the Absidia coerulea mycelia. To improve the low molecular weight chitosan production, the solid-state fermentation media were optimised to investigate the influence of substrate and supplemental medium components on low molecular weight chitosan production. The low molecular weight chitosan was obtained after treatments with 2% NaOH and 10% acetic acid. Maximal low molecular weight chitosan production was 6.12 g/kg substrate. Gel permeation chromatography combined with laser light scattering gave a molecular weight of 6.4 kDa with Mw/Mn of 1.09. Fourier transform infrared (FTIR), X-ray diffraction and 13C NMR spectra of the product showed typical peak distributions the same as those of standard chitosan which confirmed the extracted product to be chitosan-like. The method provided a new, simple and green technology to produce low molecular weight chitosan directly (Wang et al., 2008). The existence of chitosan in nature was discovered when it was isolated from the yeast Phycomyces blakesleeanus (Kreger, 1954). Chitosan occurs as the major structural component of the cell walls of certain fungi, mainly of the Zygomycetes species (Davies and Bartnicki-Garcia, 1984). However, to date, chitosans have been produced commercially by alkaline deacetylation of crustacean chitins, but experimental samples are available from other animals, such as houseflies and honey bees (Draczynski, 2008).

31.3

Properties of chitosans and derivatives

31.3.1 Solubility The solubility of chitin is remarkably poorer than that of cellulose, because of the high crystallinity of chitin, supported by hydrogen bonds mainly involving

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the acetamido and alcoholic groups. The insolubility of chitin is also pointed out as a serious drawback, nevertheless all chitins become soluble with the aid of hypochlorite as 6-oxychitins (Muzzarelli et al., 1999), and beta-chitin becomes soluble in a number of chemicals such as calcium chloride saturated methanol, among others (Nagahama et al., 2008). The presence of a prevailing number of 2-amino-2-deoxyglucose units in a chitosan allows the polymer to be brought into solution by salt formation. Chitosan is a primary aliphatic amine that can be protonated by selected acids, the pK of the chitosan amine being 6.3. The following salts, among others, are water soluble: formate, acetate, lactate, malate, citrate, glyoxylate, pyruvate, glycolate; the solubility of chitosan ascorbate depends on the preparation conditions. Under particular conditions chitin and chitosan can give hydrophilic water swellable hydrogels: gel formation is also promoted by crosslinking agents or organic solvents, particularly for chitosan derivatives. Chemical and physical gels are produced, thermally reversible and not reversible. Chitosan is insoluble in organic solvents, in acids at high concentrations and in alkali; it is also insoluble in aqueous solution at pH 6, except for low molecular weight samples. Chitosan is soluble in aqueous acidic media, following protonation of amino groups in the repeating unit; this polycationic structure is unique, other polysaccharides usually being neutral or anionic. Chitosan is also soluble in alkaline solutions (ammonium bicarbonate, pH 10) where it forms glycosylamine functions (Muzzarelli et al., 2003). The selective introduction of saccharide residues at the chitosan amino group facilitates the conversion of the water-insoluble chitosan into various branched derivatives soluble in both neutral and slightly acidic (pH 5±6) aqueous media, with solubility being attained for some products with degree of substitution as low as 0.14. Chitosan can be reacetylated with acetic anhydride to obtain also water-soluble partially reacetylated chitin (Hirano and Horiuchi, 1989). The formation of derivatives suitable for industrial applications with good solubility in various organic solvents can be effected through the introduction of hydrophobic substituents by acylation with long chain fatty acyl halides or anhydrides. As reported for polyelectrolyte chains, the intrinsic viscosity of chitosan samples in aqueous solutions depends upon the ionic strength of the medium: plots of intrinsic viscosity vs. the reciprocal of the square root of the intrinsic viscosity are linear, and the intrinsic viscosity decreases with increasing salt concentration in the system is due to the shielding effect of the counter-ions. The chitosan molecule is rather stiff, less than DNA but more than polyacrylate; increasing acetylation leads to a more extended conformation and an even stiffer chain. It was confirmed that this is due to intra-residue hydrogenbonding between the carbonyl oxygen of the N-acetyl group and H6 in the next unit. A persistence length of ca. 22 nm was found, which is lower than that of chitin (ca. 35 nm) and the existence of a cholesteric mesophase was demonstrated (Terbojevich et al., 1991). Hydrophobic derivatives of chitosan, containing a small number of hydrophobic side chains, can be obtained from long chain acyl chlorides or


855

anhydrides. A series of N-alkylchitosans (C3±C12) was obtained by reacting chitosan acetate in an ethanol±water mixture with the desired aldehyde and reducing the Schiff base with sodium cyanoborohydride (3 moles per mole of amine, 24 h). In aqueous solution, above a certain polymer concentration, intermolecular hydrophobic interactions lead to the formation of associations. As a consequence, these copolymers exhibit thickening properties equivalent to those observed for higher molecular weight homopolymers and play important roles as viscosity modifiers in a variety of waterborne technologies. N-Alkylated chitosans were synthesised by Michael addition reaction of chitosan and hydroxyethylacryl. The 1H NMR results indicated that the degree of substitution was from 0.18 to 1.2. The amorphous chitosan derivatives exhibited an excellent solubility in water. The thermal stability of the derivatives was lower than that of chitosan and hydroxyethylacryl-chitosan with degree of substitution higher than 1 decomposed at 226 ëC. In the presence of lysozyme, the initial degradation rate of the chitosan derivatives was dependent on the molecular weight. The antimicrobial activity of the chitosan derivatives was lower than that of chitosan (Ma et al., 2008). 31.3.2 Gelation Gel materials are utilised in a variety of technological applications and are currently investigated for advanced exploitations such as the formulation of ìntelligent gels' and the synthesis of `molecularly imprinted polymers'. A typical simple example of gel formation was provided with chitosan tripolyphosphate and chitosan polyphosphate gel beads. pH-responsive swelling ability, drug-release characteristics, and morphology of the chitosan gel bead depend on polyelectrolyte complexation mechanism and molecular weight of the enzymatically hydrolysed chitosan (Mi et al., 1999). The complexation mechanism of chitosan beads gelled in pentasodium tripolyphosphate or polyphosphoric acid solution was ionotropic crosslinking or interpolymer complex, respectively. The chitosan-polyphosphoric acid gel bead is a better polymer carrier for the sustained release of anticancer drugs in simulated intestinal and gastric juice media than the chitosan-tripolyphosphate gel beads. Acylation Chitosan can be efficiently N-acylated without concomitant hydroxyl modifications, using anhydrides (2±3-fold excess) in organic media; quantitative or near quantitative acylations are accomplished at room temperature within a few minutes. Further improvements in chitosan reaction rate are obtained using a number of pre-treatment methods. Mixed N- and O-acylated products are prepared under similar conditions, using 10-fold excess anhydride (Yalpani, 1988). One of the simplest ways to prepare a chitin gel is to treat chitosan acetate salt solution with carbodiimide to restore acetamido groups. Thermally irreversible gels are obtained by N-acylation of chitosans: N-acetyl-, N-propionyl- and

856


N-butyryl chitosan gels are prepared using 10% aqueous acetic, propionic and butyric acid as solvents for treatment with appropriate acyl anhydride. Both Nand O-acylation are found, but the gelation also occurs by selective N-acylation in the presence of organic solvents, as methanol, formamide and ethylene glycol. The importance of many variables has been studied by determining their effects on the gelation, such as chitosan and acyl anhydride concentrations, temperature, molecular weight of acylating compound, and extent of N-acylation. Probably the gelation is due to the aggregation of chitosan chains through hydrophobic bonding. Chitosan gels can also be prepared by using large organic counter-ions. The process involves mixing heated solutions of chitosan acetate and of the sodium salt of either 1-naphthol-4-sulphonic acid or 1-naphthylamine-4-sulphonic acid, the mixture gelling on cooling: the chitosan concentration required for gel formation is low, about 2±5 g/l, and similar to the concentrations used for gel formation with other polysaccharides such as the carrageenans. Gel-like properties were found in N-carboxymethyl chitosan: this behaviour was explained in terms of association of ordered chains into a cohesive network, analogous to that in normal gels but with weaker interactions between associating chains, i.e., a weak gel (Lapasin et al., 1996). Chitosan gel beads could be prepared in amino acid solutions of about pH 9, despite the requirement for a pH above 12 for gelation in water (Kofuji et al., 1999). This phenomenon was observed not only in amino acid solutions but also in solutions of compounds having amino groups. A solute concentration of more than 10% was required for preparation of gel beads at pH 9. Gelation of the chitosan beads required about 25±40 minutes depending on the species of amino acid. pH-Sensitive hydrogels were synthesised (Qu et al., 1999a,b) by grafting D,Llactic acid onto the amino groups in chitosan without a catalyst; polyester substituents provide the basis for hydrophobic interactions that contribute to the formation of hydrogels. The swelling mechanisms in enzyme-free simulated gastric fluid (pH 2.2) or simulated intestinal fluid (pH 7.4) at 37 ëC were investigated. The crystallinity of chitosan gradually decreased after grafting, since the side chains substitute the ±NH2 groups of chitosan randomly along the chain and destroy the regularity of packing between chitosan chains. Enzymatic reactions leading to gels Stable and self-sustaining gels were obtained from tyrosine glucan (a modified chitosan synthesised by reaction of chitosan with 4-hydroxyphenylpyruvic acid) in the presence of tyrosinase that oxidises the phenol to quinone, thus starting crosslinking with residual free amino groups. Gels were also obtained with 3hydroxybenzaldehyde, 4-hydroxybenzaldehyde and 3,4-dihydroxybenzaldehyde (Muzzarelli and Ilari, 1994; Muzzarelli et al., 1994; Chen et al., 2003). As an extension of these works, a mushroom tyrosinase was observed to catalyse the oxidation of phenolic moieties of the synthetic polymer poly(4hydroxystyrene) in water-methanol. Although oxidation was rapid, in the order


857

of minutes, only a small number of phenolic moieties (1±2%) underwent oxidation. Enzymatically oxidised poly(4-hydroxystyrene) was observed to undergo a subsequent non-enzymatic reaction with chitosan, based on UV spectra (Shao et al., 1999; Kumar et al., 1999). Further progress (Edwards et al., 1999a,b) led to internally skinned polysulphone capillary membranes coated with a viscous chitosan gel and useful as an immobilisation matrix for polyphenol oxidase. Bench-scale, single-capillary membrane bioreactors were then used to determine the influence of the chitosan coating on product removal after substrate conversion by immobilised polyphenol oxidase during the treatment of industrial phenolic effluents. The results indicate that greater efficiency was achieved in the removal of polyphenol oxidase-generated products by the chitosan membrane coating, as compared with chitosan flakes. Dilute solutions of chitosan with 3,4-dihydroxyphenylethylamine (dopamine) become hydrogels within a short time by virtue of the tyrosinase-catalysed oxidation of dopamine to quinone: the viscosity of the chitosan solutions greatly increases as a result of the immediate reaction of quinone with the chitosan amino groups that confers water-resistant adhesive properties to the gel (Yamada et al., 2008). NaCl particles (porogen) and gamma-glycidoxypropyltrimethoxysilane (crosslinking agent) were used to make chitosan-silica porous hybrid membranes with optimal chitosan/crosslinker weight ratio 1. Macropores (ca. 10±202 m) in the membrane matrix, and micropores (8±10 nm) within the macropores were observed. Histidine, glutamic acid, tyrosine, L-DOPA, and p-aminobenzoic acid were individually linked onto said material with the aid of genipin: the paminobenzoate chitosan membrane exhibited the best affinity adsorption of tyrosinase from a crude Agaricus bisporus solution (Chao, 2008). Hydrogels of chitosan crosslinked with genipin appear to be most biocompatible and safe as indicated in a recent review article (Muzzarelli, 2009c). A biosensor was fabricated by immobilising tyrosinase on the surface of multiwalled carbon nanotubes±chitosan composite modified glassy carbon electrode. The composite film provided a biocompatible platform for the tyrosinase to retain the bioactivity and the nanotubes possessed excellent inherent conductivity to enhance the electron transfer rate. The biosensor showed high sensitivity (412 mA/M), broad linear response, low detection limit (5.0 nM) and good stability for determination of phenol. The biosensor was further applied to rapid detection of the coliforms, represented by Escherichia coli that could be detected as low as 10 colony-forming units (CFU) per ml (Cheng et al., 2008). Reactions with aldehydes The Schiff reaction between chitosan and aldehydes and ketones gives the corresponding aldimines and ketimines, which can be converted to N-alkyl derivatives on hydrogenation with cyanoborohydride. A wide range of aliphatic and aromatic carbonyl compounds have been used, including formaldehyde, unsaturated alkyl aldehydes, aldehydo and keto acids, carbonyl-containing

858


carbohydrates and dialdehydes, such as glutaraldehyde. In particular, Ncarboxymethyl chitosan was obtained in a water-soluble form by a proper selection of the reactant ratios, i.e., using equimolecular quantities of glyoxylic acid and amino groups (Muzzarelli, 1988). Fully substituted N,N 0 -dicarboxymethylchitosan was obtained by the alkylation of chitosan at pH 8±8.5 and 90 ëC using a monochloroacetic acid : chitosan weight ratio of 4:1. The water-soluble derivative is suitable for applications involving chelation (An et al., 2008). The reaction with 2-oxoglutaric acid under reducing conditions gave glutamate glucan. The attachment of various reducing mono-, oligo- and polysaccharides to chitosan, under mild conditions and in the presence of sodium cyanoborohydride, affords products with degree of substitution 0.54±0.97 in high yields (70±100%, depending on the residue length). Reductive alkylations were also performed with other types of saccharides, such as fructose, streptomycin sulfate and selectively oxidised betacyclodextrin (Yalpani, 1988). Studies on intestinal permeation enhancers were also reviewed as they provide information on the mechanism of action and safety of polymers. The active polymers are classified into: polycations (chitosan and its quaternary ammonium derivatives, poly-L-arginine, aminated gelatin), polyanions [Ncarboxymethyl chitosan, poly(acrylic acid)], and thiolated polymers (carboxymethyl cellulose-cysteine, polycarbophil-cysteine, chitosan-thiobutylamidine, chitosan-thioglycolic acid, chitosan-glutathione conjugates) (Di Colo et al., 2008). Glutaraldehyde is a very popular crosslinking agent for chitosan (Muzzarelli et al., 1976). Chitosan networks were obtained by reaction with glutaraldehyde in lactic acid solution (pH 4±5). The rheology of the chitosan-glutaraldehyde gel system was studied by Arguelles-Monal et al. (1998). By reaction of chitosan with aldehydes, N-alkylidene or N-aryldene chitosan gels are produced; the extent of modification of the amino groups is about 80% and the minimum amount of aldehyde required for gel formation increases by increasing the aldehyde molecular weight. In the search for biocompatible hydrogels based exclusively on polysaccharide chains, chitosan and the dialdehyde obtainable from scleroglucan by controlled periodate oxidation were linked together (Crescenzi et al., 1995); the reaction takes place at pH 10 and the reduction of the resulting Schiff base is performed with NaBH3CN. The swelling capacity of the hydrogel is remarkable, considering the highly hydrophilic character of both polysaccharides, and strongly depends on the pH of the bathing solutions. Likewise, -cyclodextrinmodified chitosan was synthesised via the Schiff base reaction with 6-O-(4formylphenyl)- -cyclodextrin (Liu et al., 2008), as well as a variety of chitosans containing aromatic groups (Sajomsang et al., 2008); the use of glutaraldehyde in most diverse applications does not decline at all. A semi-interpenetrating network was synthesised with poly(ethylene oxide) and chitosan, and crosslinked with glyoxal (Khalid et al., 1999). Swelling studies were performed on the chitosan/poly(ethylene oxide) semi-


859

interpenetrating network and on the reference hydrogel (crosslinked chitosan) at pH 1.2 and 7.2. The semi-interpenetrating network displayed a high capacity to swell, adjustable by pH. Rheological studies performed in simple shearing and in oscillation showed that the semi-interpenetrating network had elastic properties. Poly(ethylene glycol) dialdehyde diethyl acetals of different molecular sizes were synthesised and used to generate in situ PEG dialdehydes for the crosslinking of partially reacetylated chitosan via Schiff reaction and hydrogenation of the aldimines. The water-soluble products obtained were instrumentally characterised. Upon freeze-drying, they aggregated to yield insoluble soft and spongy biomaterials that swelled immediately upon contact with water. When exposed to papain and lipase, at physiological pH values, progressive dissolution of the biomaterials was observed, but no dissolution took place with lysozyme, collagenase and amylase. They were found to be biocompatible (DalPozzo et al., 2000). A continuation of this work was provided by Deng et al. (2007) who reported on the reaction with the counter-ion tripolyphosphate, and formation of nanoparticles. 31.3.3 Polyelectrolyte complex formation At high degree of protonation of the amino groups, chitosan spontaneously forms macromolecular complexes by reaction with anionic polyelectrolytes. These complexes are generally water insoluble and make hydrogels. Several reviews on polyelectrolytes have been published (Tsuchida and Abe, 1982; Kubota and Kikuchi, 1999; VanTomme et al., 2008). A variety of polyelectrolytes can be obtained by changing the chemical structure of component polymers, such as molecular weight, flexibility, functional group structure, charge density, hydrophilicity and hydrophobicity, stereoregularity, and compatibility, as well as changing reaction conditions, such as pH, ionic strength, polymer concentration, mixing ratio and temperature. This, therefore, may lead to diverse physical and chemical properties of the complexes. Polyelectrolytes of chitosan with other polysaccharides, proteins, DNA and synthetic and inorganic polymers were investigated. A hydrogel with high sensitivity to the change in external pH was prepared between chitosan (DA = 0.18) and dextran sulfate (Sakiyama et al., 1999): the maximum volume of the complex gel was observed in a dilute NaOH solution at pH 10.5, and was about 300 times as large as the volume at pH values below 9 (Jiang et al., 1999). Nanoparticle made of two bioadhesive polysaccharides, hyaluronan and chitosan, were obtained by a very mild ionotropic gelation technique. The nanoparticles had a size in the range of 100 to 235 nm and a zeta-potential of ÿ30 to 28 mV. Toxicological studies were conducted in human corneal epithelial and conjunctival cell lines. The confocal images indicated that the nanoparticles were internalised by fluid endocytosis and that this endocytic process was mediated by the hyaluronan receptor CD44 (DeLaFuente et al., 2008a,b). Hyaluronan-chitosan nanoparticles made of low molecular weight chitosan (10±12 kDa) led to high levels of expression of secreted alkaline phosphatase in

860


the human corneal epithelium model. Following topical administration to rabbits, these nanoparticles entered the corneal and conjunctival epithelial cells and were assimilated by the cells. More importantly, the nanoparticles provided an efficient delivery of the associated plasmid DNA inside the cells, reaching significant transfection levels (DeLaFuente et al., 2008a,b). Hydrogels composed of poly(N-isopropylacrylamide) with chitosan (Fang et al., 2008) or , -glycerophosphate with chitosan (Zhou et al., 2008) can be mentioned as examples of temperature-sensitive hydrogels with transition at 37 ëC.

31.4

Chitin as a food component

Crustaceans, insects, rodents, frogs, snails, earthworms, spiders, scorpions, centipedes, and millipedes have been used as food sources for millennia. A close examination of the world insect consumption shows that more than 2,000 edible species have been utilised as a food source, although this is deemed to be underreported and research will increase this number (Paoletti, 2005; Backwell and D'Errico, 2001; DeFoliart, 1992, 1999). Currently preferred insects are listed in Table 31.1. On the other hand, of the 15 million plants, animals and microbes on Earth, more than 90% of the world's food supply comes from just 15 crop species and 8 livestock species. Chitin digestion requires chitinolytic enzymes: chitinases are present in plant foods, and human and bacterial chitinolytic enzymes occur in the human digestive apparatus. The bibliographic data confirm the presence of chitinolytic enzymes in plant organs, and thus vegetables and fruits that are consumed by humans could help in the digestion of chitin. Although the level of plant chitinases is often correlated to the presence of stress, such as infections, these enzymes also occur in healthy plant tissues and above all in fruits under maturation, which are most often used in human nutrition (Taira et al., 2004; Truong et al., 2003). For examaple, the phyla Leguminosae have lectins, chitinases and glycohydrolases as major defence proteins in their seeds. Electrophoresis of the proteins of tamarind (Tamarindus indica L.) indicated the presence of a 34 kDa class III endochitinase (Rao and Gowda, 2008). Table 31.1

Consumption of insects as food in the world

Continent

Species

Africa Central and South America

524 679

Asia

349

Australia

152

Most popular insects cooked and eaten Gonimbrasia belina (grub) Rhynchophorus spp (snout beetle) Aegiale hesperiaris (butterfly) Atta spp (ant) Locusta spp Bombyx mori (silk worm) Rhychophorus ferrugineus papuanus


861

Chitin digestion by humans has generally been questioned or denied. Only recently have chitinases been found in several human tissues and their role has been associated with defence against parasite infections and to some allergic conditions. The gastric juices of 25 Italian subjects were tested on the artificial substrates 4-methylumbelliferyl- -D-N,N 0 -diacetylchitobiose and fluorescein isothiocyanate chitin to demonstrate the presence of a chitinase activity currently called acidic mammalian chitinase. It was found to be present in gastric juices of 20 out of 25 Italian patients in a range of activity from 0.21± 36.27 nmol/ml.hÿ1. In the remaining five gastric juices, the chitinase activity was almost absent. The allosamidine inhibition test and the measurement at different pH values confirmed that this activity was characteristic of a chitinase. The absence of activity in 20% of the gastric juices may be a consequence of virtual absence of chitinous food in the western diet (Paoletti et al., 2007). In the excreta of healthy people there is at least a bacterial species able to hydrolyse chitin to N-acetyl glucosamine. Clostridium paraputrificum in the human colon is able to synthesise and secrete chitinases and -N-acetyl glucosaminidase, that could take part in the digestion of chitin. Similarly, chitotriosidase, a chitinase produced by activated macrophages is able to hydrolyse chitin (Malaguarnera, 2006; Piras et al., 2007; Gianfrancesco and Musumeci, 2004; Renkema et al., 1995, 1998). An inherited deficiency in chitotriosidase activity is frequently reported in the plasma of Caucasian subjects, whereas this deficiency is rare in the African population. The study by Musumeci et al. (2005) compares chitotriosidase activity in the colostrum of 53 African women and 50 Caucasian women. Elevated chitotriosidase was found in the colostrum of African women on the first day after delivery (1230 662 nmol/ml.hÿ1) which decreased with time. The chitotriosidase activity on the first day after delivery in the colostrum of Caucasian women, however, was significantly lower (293 74 nmol/ml.hÿ1) and decreased to 25 20 and 22 19 nmol/ml.hÿ1 on the second and third day, respectively. The chitotriosidase activity in the plasma of African women was also higher (101 80 nmol/ml.h ÿ1 ) than that of Caucasian women (46 16 nmol/ml.hÿ1), but no correlation was found between the plasma and colostrum activities. The elevated chitotriosidase activity in the colostrum of African women is indicative of the presence of activated macrophages in human milk, consistent with the genetic characteristics of the African population, and their chitin eating habits. In fact, a chitin-rich diet induces the secretion of human chitinases.

31.5

Nutritional and health effects

A number of European countries as well as the United States and some oriental countries (Japan, South Korea) have approved the sale of chitosan-based nutraceuticals as over-the-counter products for the control of obesity, hypercholesterolemia and hypertension. Chitosan, in this context, is generally

862


regarded as safe, being a partially deacetylated chitin, i.e. a polysaccharide widely present in nature, in particular in human food such as certain cheeses and marine animals including crustaceans and squids. The chitosans used to prepare dietary supplements come, in fact, from crustaceans, mainly shrimps. The freshly caught crustaceans are peeled in the canning and freezing factories, and while the meat is canned or packed, the shells are collected and treated by chemical or microbiological means, in order to extract chitin. It has been verified that seasonal fluctuations and varieties of shrimps and squids caught during fishing activities introduce negligible differences in the chitosans resulting from the chitin extraction (Lavall et al., 2007); novel technologies have been experimented with, but with limited success (Kjartansson et al., 2006). The exposure of chitin to acids, alkali, surfactants, solvents for the extraction of carotenoids, and the submission of the chitosan flakes to drying, milling, sieving and other operations, introduce more diversity among various lots of chitosan. Thermal drying, for instance, may introduce a limited degree of crosslinking while the degree of deacetylation of the final chitosan may depend on the grain size of the chitin powder exposed to hot alkali during the deacetylation process. To date, there is no chitosan standard for any application. In other words, even though various grades are available such as technical, food and medical grades, no clear recommendation has been made and accepted for adopting a chitosan standard in food applications. As a consequence the chitosan currently used to manufacture chitosan tablets for human consumption are chosen mainly on the basis of their constant supply and economical convenience. In the eyes of today's producers, their characteristics are a secondary aspect and in general only the degree of acetylation, the viscosity and the microbiological contamination are certified. The producers do not declare the degree of crystallinity, the polydispersity of the molecular weight, the presence of amino acids and metals. Therefore it is difficult to predict the performances of the dietary supplements. A further aspect of uncertainty is introduced by the preparation of the tablets: the tendency is to adopt the most usual tabletting process regardless of the consequences that certain excipients have on chitosan activity in vivo. For example, tabletting involves the use of a binder in order to hold together the poorly compressible chitosan powder. Magnesium stearate, a slightly soluble compound, once coated on the chitosan powder, deeply alters the capacity of chitosan to react or effectively contact other compounds. Site-specific controlled release systems have been extensively investigated during the last decade. Chitosan salts with succinic acid, adipic acid, and suberic acid were prepared by spray-drying and were coated with stearic acid by the same technique. In a study the carriers were characterised in terms of morphology, size, swelling, mucoadhesive properties and drug loading, and focused on the in vitro influence of chitosan salts on the release behaviour of vancomycin hydrochloride from the uncoated and coated systems at pH levels of 2.0, 5.5 and 7.6 (Bigucci et al.,


863

2008). The results of the study supports the view that chitosan tablets containing stearate salts might lack full anti-hypercholesterolhaemic activity simply because the stearate excipient prevents hydrogel formation in the stomach and effective contact with bile salts. 31.5.1 Cholesterol lowering in humans Chitosan was first shown to reduce serum cholesterol in humans in 1993, when adult males fed chitosan-containing meals for two weeks (3 g/d for week 1, 6 g/d for week 2) experienced 6% decrease in total cholesterol (Maezaki et al., 1993). The subjects also exhibited a 10% increase in high density lipoprotein cholesterol. Two studies have reported serum cholesterol reductions with chitosan treatment. Obese women consuming 1.2 g of microcrystalline chitosan for 8 weeks demonstrated significant reductions of low density lipoprotein, although not total serum cholesterol. A total of 84 female subjects with mild to moderate hypercholesterolemia receiving 1.2 g of chitosan per day experienced a significant decrease in total serum cholesterol (Bokura and Kobayashi, 2003). Metso et al. (2003) observed 83 middle-aged men and women without severe disease and with a total cholesterol of 4.8±6.8 mmol/l and triglycerides below 3.0 mmol/l. Their conclusion was that treatment with microcrystalline chitosan had no effect on the concentrations of plasma lipids or glucose in healthy middle-aged men and women with moderately increased plasma cholesterol concentrations. For oral administration to humans, chitosan is generally recognised as safe (Harrison, 2002; Kumar et al., 2004). Some 21 overweight normocholesterolemic subjects were fed a supplement containing equal amounts of glucomannan and chitosan for 28 days: the observed serum cholesterol reduction was mediated by increased faecal steroid excretion and was not linked to fat excretion. Greater faecal excretion of neutral sterols and bile salts was observed. The topic has been reviewed by Muzzarelli and Muzzarelli (2006) and by Pittler and Ernst (2004). In Sprague±Dawley rats, chitosan did not affect food intake but decreased body weight gain and significantly increased faecal fat and cholesterol excretion, reduced the lipid level in plasma and liver, increased liver hepatic and lipoprotein lipase activities (Zhang et al., 2008). To understand the mechanism of cholesterol lowering by chitosan, one should consider first that bile salts are formed from cholesterol in the liver and are secreted into the duodenum by the enterohepatic circulation: the bile salt pool is maintained stable, the newly ingested cholesterol compensating the excreted quantities. If, however, bile salts are sequestered by any suitable compound, some cholesterol is oxidised to produce more bile salts. Bile is produced at the rate of 700±1200 ml/day, bile salts accounting for 1.24±1.72%, cholesterol for 0.86±1.76 g/l; the average pH is 7.3. For the various intestinal tracts, the pH values are as follows: duodenum 4.7±6.5, upper jejunum 6.2±6.7, lower jejunum 6.2±7.3, ileum 6.1±7.3, colon > 7.3. It is worth noting that these

864


values tend to keep the bile salts in solution, while depressing the chitosan solubility (chitosan pK = 6.3). The uptake of bile salts into chitosan-alginate gel beads was observed by Murata et al. (1999): the presence of weak acids (orotic, citric, folic and ascorbic) does not hinder the uptake; rather, chitosan orotate salt was found to enhance it. Various chitosans and heavily modified ChitopearlÕ chitosans were studied by Murata et al. (2003) and found to have capacities in the range 0.53± 1.20 mmol taurocholate per gram of chitosan (various degrees of acetylation) and 0.2±0.9 mmol taurocholate for ChitopearlÕ products; the capacity of QuestranÕ was ca. 1.0 mmol taurocholate/g. Higher capacities were observed for taurodeoxycholate (1.8 mmol taurodeoxycholate/g chitosan). Of course, these capacities depend on the initial bile salt concentration, grain size and other parameters. One millimole of taurocholate corresponds to 515 mg, thus the weight ratio taurocholate/chitosan orotate is 0.515 : 1.000, which appears to be a high ratio, notwithstanding the uncertainties related to the description of the experimental conditions. By using chitosan cinnamate and analogue compounds such as those of vanillic acid, hydroxycinnamic acids, cumaric acids and rosmarinic acid, the bile acid adsorption and the release of cinnamate were investigated in vitro. When chitosan cinnamate was soaked in a taurocholate solution, it adsorbed the bile acid while simultaneously releasing cinnamate. The amount of cinnamate analogue released was 0:286 0:001 mmol/g, practically coincident with the amount of taurocholate adsorbed. The amount of released cinnamate analogue was altered extensively by the species of analogue used for gel-bead preparation. Results were indicative of high affinity of taurocholate for chitosan, and suggest that those compounds may be of interest for complementary medicine to prevent lifestyle-related diseases (Murata et al., 2006). Eleven chitosan samples were evaluated for their fat- and bile acid-binding capacities, physico-chemical properties, and the correlations between each binding capacity and individual physico-chemical properties. The bile acid- and fat-binding capacities were estimated using in vitro assays, whereas the measured physico-chemical properties were deacetylation degree, swelling capacity, and solution viscosity. Chitosan samples might differ in their binding capacities against fat and/or individual bile acids. The bile acid-binding capacities were 0.20±0.61, 0.43±1.63 and 0.61±1.61 micromol/g chitosan for cholic, deoxycholic, and chenodeoxycholic acids, respectively. Stronger binding capacity of chitosan against a selected bile acid did not imply greater binding capacity for other bile acids (Zhou et al., 2006). Thongngam and McClements (2005 a,b) provided thermodynamic data by isothermal titration calorimetry on the binding of Na taurocholate to chitosan. At 30 ëC, Na taurocholate binds strongly to chitosan to form an insoluble complex containing ca. 4 mmol Na taurocholate/g chitosan at saturation, that means taurocholate : chitosan molar ratio ca. 2 : 3 and weight ratio ca. 2 : 1. Ionic strength had scarce influence; the enthalpy changes went from endothermic (at 10 ëC) to exothermic (at 40 ëC) indicating the importance of changes of


865

hydrophobic interactions leading to the formation of micelle-like clusters within the chitosan structure. The binding capacities of sodium glycocholate to chitosan, diethylaminoethyl chitosan, quaternised diethylaminoethyl chitosan, and cholestyramine were 1.42, 3.12, 4.06 and 2.78 mmol/g, respectively. The capacity of dialkylaminoalkyl chitosans increased with the number of carbons in the alkyl groups, indicating that hydrophobic interaction plays a major role in the sequestration of bile acids (Lee et al., 1999); similarly, the capacity of 6oxychitosan for cholic acid decreases with increasing degree of oxidation, i.e., loss of cationicity (Yoo et al., 2005). Among the chitosan salts that instantly form from chitosan and bile acids in vitro, chitosan taurocholate appears to possess infrared spectral characteristics that qualify it as a real ionic, water-insoluble, poorly crystalline, hydrophobic chitosan salt. In chitosan taurocholate and homologues, chitosan accounts for no more than one half by weight, therefore the hydrophobic nature prevails when contacting lipids. Butter and oils are collected to high extents with no discrimination of their components, including cholesterol and tocopherols. For these chitosan salts the lipid uptake is much higher than for plain chitosan. The salts studied in the present work are scarcely hydrolysed by a variety of hydrolases, and it is presumed that their complexes with lipids would be even more resistant to enzymatic attack. If the above findings are extrapolated from the in vitro model to the physiological environment, it seems reasonable to speculate the following: · Chitosan glycocholate and chitosan taurocholate insoluble salts subtract bile salts from the circulation thus forcing the organism to replete the bile pool at the expenses of cholesterol. · The activity of lipases on triglycerides is depressed as a consequence of the poor emulsification of lipids due to the lowered availability of taurocholate, the emulsifier. It is known that the pancreatic lipases require a certain dimension of the oil droplets in the emulsion in order to hydrolyse triglycerides: now, when the bile salts become scarce, inadequate emulsions are formed and then limited hydrolysis of triglycerides takes place. Ample information on digestive lipases supports these views (Mukherjee, 2003) that have been experimentally confirmed (Helgason et al., 2008). Lipases work thanks to the presence of bile salts that in one case activate the bile saltsdependent lipases, and in the other case provide the emulsion necessary to the pancreatic lipases for enzymatic activity. Moreover, as soon as the bile salt availability decreases due to chitosan ingestion, the bile salts-dependent lipases are poorly activated, and assimilation of lipids by the organism decreases sharply. · While pectinase is one of the most representative bacterial enzymes in the intestine, the resistance of the chitosan taurocholate, glycocholate and taurodeoxycholate salts to hydrolysis by this enzyme, as well as by other hydrolases, would certainly be an indication of the capacity of these hydrophobic salts to be excreted, presumably with accompanying adsorbed lipids.

866


Table 31.2 Time (min) necessary for total digestion of freeze-dried chitosan salts suspended in aqueous solutions of animal, fungal and plant enzymes at 20 ëC and optimum pH Enzyme

Cellulase, Trichoderma reesei Alpha-amylase, barley malt Alpha-amylase, porcine pancreas Pectinase, Aspergillus niger Lysozyme, hen egg white Lipase, wheat germ Lipase, porcine pancreas

CTC

CGC

CTDC

pH

min

pH

min

pH

min

6.8 7.1 6.8 7.1 7.3 6.7 7.3

60 1440 no no 30 no no

6.6 7.0 6.8 6.9 7.0 6.6 7.0

90 1440 no no 4.5 no no

6.5 4.5 7.0 6.4 7.0 6.7 6.9

no no no no no no no

CTC = chitosan taurocholate; CGC = chitosan glycocholate; CTDC = chitosan taurodeoxycholate. No = No appreciable digestion after 48 hours. Source: Muzzarelli et al. (2006).

Upon mixing a solution of Na taurocholate with a solution of chitosan acetate, both at pH values close to 4, immediate precipitation of chitosan taurocholate salt is observed. The salt obtained with nearly stoichiometric amounts of both reagents was characterised by infrared spectrometry, and found to exhibit new bands indicative of its ionic nature. Similar compounds were obtained from Na taurodeoxycholate and Na glycocholate. When exposed to a number of hydrolases at pH values close to neutrality and 20 and 37 ëC, they were found to be poorly susceptible to enzymatic degradation: only Trichoderma reesei cellulase, egg white lysozyme and barley malt -amylase were effective on chitosan taurocholate and glycocholate, as shown in Table 31.2. The observed capacities of the freeze-dried salts for olive oil were 22 g oil/ g of chitosan taurocholate, 60 g oil/g of chitosan glycocholate, and 27 g oil/g of chitosan taurodeoxycholate. The capacities were 22.1 g butter oil/g of chitosan taurocholate and 22.1 g of corn oil/g chitosan taurocholate. These data, substantially much higher than similar data published for plain chitosan and various oils, mean that the lipid uptake takes place mainly by hydrophobic interactions with the insoluble salts formed by chitosan upon contact with bile (Muzzarelli et al., 2006). 31.5.2 Overweight control Fourteen published trials including a total of 1,131 participants met the inclusion criteria in a study by NiMhurchu et al. (2005a,b) published in review format by Jull et al. (2008). Analyses including all trials indicated that chitosan preparations result in a significantly greater weight loss (weighted mean difference ÿ1.7 kg; 95% confidence interval (c.i.) ÿ2.1 to ÿ1.3 kg), decrease in total cholesterol (ÿ0.2 mmol/L; 95% c.i. ÿ0.3 to ÿ0.1), decrease in systolic (ÿ5.9 mmHg; 95% c.i. -7.3 to -4.6) and diastolic (ÿ3.4 mmHg; 95% c.i. ÿ4.4 to


867

ÿ2.4) blood pressure compared with placebo. If recalculated in terms of mg/dl, the loss of cholesterol is 3-4%, i.e., clinically significant. It was remarked that the quality of certain studies was sub-optimal. The conclusions were that evidence exists that chitosan is more effective than placebo in the short-term treatment of overweight and obesity. NiMhurchu et al. (2004) also conducted a 24-week randomised, double-blind, placebo-controlled trial, with a total of 250 participants (82% women; mean (s.d.) body mass index, 35.5 (5.1) kg/m2; mean age, 48 (12) y). The chitosan group lost more body weight than the placebo group (mean (s.e.), ÿ0.4 (0.2) kg (0.4% loss) vs +0.2 (0.2) kg (0.2% gain), P = 0.03) during the 24-week intervention. Studies of the effect of chitosan on human adiposity suggest that results may differ depending on whether the subjects are eating ad libitum or are on a weight loss diet. Overweight subjects consuming 2.4 g/day of chitosan for 28 days, also consuming their normal diet, showed no change in body weight during the trial (Gallaher et al., 2002). A six-week study was conducted on obese adults who lost more body weight (-2.3 vs 0.0 kg), body fat (-1.1 vs 0.2%) and absolute fat mass (-2.0 vs 0.2 kg). The combination of glucomannan, chitosan, fenugreek Gymnema sylvestre and vitamin C were therefore effective (Woodgate and Conquer, 2003). Gades and Stern (2005) tested the fat-trapping capacity of a chitosan product in 12 men and 12 women. Faecal fat excretion increased with chitosan by 1:8 2:4 g/day in males, but did not increase with chitosan in females: therefore fat-trapping claims should not be generalised. Chitosan greatly increases faecal fat excretion when consumed in sufficient amounts and can accelerate weight loss when subjects follow a low calorie diet, but will be ineffective in those consuming their habitual diets.

31.6

Food industry applications

Chitosan, whose applications in the food industry have been reviewed by Rudrapatnam and Farooqahmed (2003) exhibits antimicrobial activity against a range of food-borne micro-organisms and consequently has attracted attention as a potential natural food preservative (Chen et al., 1998; El Ghaouth et al., 1992; Shahidi et al., 1999). Binding of trace metals and effect on membrane permeability have been postulated to be the main mechanisms for its antibacterial action (Helander, 2001; Zheng and Zhu, 2003). Muscle foods have low oxidative stability and are very susceptible to rancidity during production and storage. Numerous studies have indicated that lipid oxidation in meat and meat products may be controlled or minimised through the use of antioxidants (Gray et al., 1996; Nissen et al., 2004; Rhee, 1987). However, chitosan has a bitter taste, which may limit the use of artificial antioxidants in meat and meat products, when flavour is an important consideration. The antimicrobial and antioxidant potential of spices and herbs, such as basil, thyme, rosemary, garlic, clove, coriander, ginger, mustard and pepper are well

868


known (Georgantelis et al., 2007a,b; Sebranek et al., 2005; Tipsrisukond et al., 1998). Mint (Mentha spicata) is used extensively (Choudhury et al., 2006). The mint extract has very good antioxidant potential, comparable to that of the synthetic antioxidant butylated hydroxy toluene (Kanatt et al., 2007, 2008). Mint extract did not show any antibacterial activity, though essential oils of some Mentha species have been reported to have antibacterial activity (Marino et al., 2001; Moreira et al., 2005). Mixed mint and chitosan efficiently scavenged superoxide and hydroxyl radicals and was particularly effective against Grampositive bacteria. The shelf-life of pork cocktail salami, as determined by total bacterial count and oxidative rancidity, was enhanced in mint + chitosan-treated samples stored at 0±3 ëC. Chitosan films prepared with oregano essential oil were applied on bologna slices. Release of the essential oil compounds during film preparation and application on the meat product and consumer acceptability of bologna enriched with oregano essential oil were found satisfactory (Chi et al., 2007). Antimicrobial and physico-chemical properties of chitosan films and chitosan films enriched with essential oils were determined in vitro and on processed meat. Antimicrobial effects of pure essential oils of anise, basil, coriander and oregano, and of chitosan-essential oil films against Listeria monocytogenes and Escherichia coli were investigated. The films have the potential to be used as active biodegradable films with strong antimicrobial effects. Edible films can provide supplementary and sometimes essential means of controlling physiological, morphological and physico-chemical changes in food products. High density polyethylene film, a common packaging material used to protect foods, has disadvantages like fermentation due to the depletion of oxygen and condensation of water, which promotes fungal growth. Due to their filmogenicity, chitin and chitosan are satisfactorily used as food wraps. Semipermeable chitosan films modify the internal atmosphere, decrease the transpiration and delay the ripening of fruits. For the preparation of chitosan/ pectin laminated films and chitosan/methylcellulose films several approaches have been used, including simple coacervation. Chitosan films are tough, flexible and tear-resistant; moreover, they have favourable permeation characteristics for gases and water vapour. Chitosan is also suitable as a texturising agent for perishable foods: for instance, high viscosity chitosan solutions were used to prepare tofu, a widely consumed oriental food, for which the organoleptic properties did not vary appreciably while shelf-life was extended (Kim and Han, 2002; No et al., 2002). Processing of clarified fruit juices commonly involves the use of clarifying agents, including gelatin, bentonite, tannins, potassium caseinate and polyvinyl pyrrolidone. Chitosan is a dehazing agent used to control acidity in fruit juices, as well as being a good clarifying agent for grapefruit juice with or without pectinase treatment, besides apple, lemon and orange juices, and a fining agent for apple juice, which can afford zero turbidity products with as little as 0.8 kg/m3 of chitosan. No impact on the biochemical parameters of the juices was found (Chatterjee et al., 2004). Apple juice can be protected from fungal spoilage with the aid of modest additions of chitosan glutamate (Roller and Covill, 1999).


869

Chitosan has a good affinity for polyphenolic compounds such as catechins, proanthocyanidins, cinnamic acid and their derivatives that can change the colour of white wines due to their oxidative products. By adding chitosan to grapefruit juice (15 g/l), the total acid content (citric, tartaric, malic, oxalic and ascorbic acid) was sharply reduced. Jang and Lee (2008) demonstrated the stability of tripolyphosphate-chitosan nanoparticles for ascorbic acid during heat processing and suggested the use of ascorbate-loaded chitosan nanoparticles to enhance antioxidant effects because of the continuous release of ascorbate from the nanoparticles in food processing.

31.7

Applications in drug delivery

The usefulness and versatility of chitosan hydrogels is particularly evident when the field of drug delivery is considered. Plain chitosan, a safe biopolymer, has been extensively applied to the human body by all possible means and for a variety of purposes: chitosan is a functional ingredient of cosmetics, a biocompatible coating for prosthetic materials, a drug delivery item, a gene vector, a dietary supplement, and a wound healing dressing capable of restoring the native histoarchitecture. In a large group of materials used to enhance absorption of drugs, chitosan ranked first in terms of maximum drug bioavailability (enhanced absorption) and minimum damage to the membranes (Illum and Davies, 2005). Of course, the limitations of plain chitosan, mainly its scarce solubility at neutral and alkaline pH values, can be overcome by selecting adequate chemical or enzymatic modifications free from adverse effects on the living tissues: for example, the derivatisation of chitosan with the aid of glyoxylic acid (the simplest aldehydoacid) leads to N-carboxymethyl chitosan that can be interpreted as a glycine derivative as well. Because glycine is one of the most abundant amino acids in the human body, in collagen for instance, N-carboxymethyl chitosan is safe in principle, as confirmed experimentally; indeed it is a functional ingredient of hydrating creams present on a niche market for more than a decade. Pyruvic acid exemplifies the ketoacids from which aminoacid glucans can be derived via ketimine formation with chitosan. Such modified chitosans were developed in the 1980s (Muzzarelli et al., 1985; Muzzarelli and Zattoni, 1986) and have found applications in various areas (Sun et al., 2007). The safety of carboxymethylated chitosans has been demonstrated by Janvikul et al. (2007). According to Sun and Wan (2007), to qualify as a drug delivery aid and absorption enhancer, a modified chitosan should exhibit hydrogel characteristics, particularly because it should remain in contact with the mucosae long enough to achieve maximum effect, and any consequence on the mucosae should be completely reversible. Other requirements are also satisfied by chitosan hydrogels, because they are generally compatible with drugs, have no odour, are non-irritating, non-toxic and non-allergenic. From the pharmaco-

870


logical standpoint, chitosans are inert at the concentrations required in practical use: they exhibit mild anti-inflammatory action. In fact, when chitosans contact the mucosal tissue a reaction takes place between the chitosan's glucosamine units and the sialic acid units of the mucin and epithelial cell membrane (Deacon et al., 1999). Therefore a decreased clearance of administered formulations and an increased absorption are observed. In a sheep model, chitosan was far superior to diethylaminoethyl (DEAE) dextran in terms of absorption enhancing effect. A reason for the difference between the two polymers was that the DEAE dextran is randomly and scarcely substituted, is a branched polysaccharide as opposed to linear chitosan that carries one primary amino group on each anhydroglucose ring. Some of the nitrogen atoms are hidden in the DEAE dextran network and are therefore unavailable for interaction with the mucosae (Harding et al., 1999). Experimental studies have led to the development of gastroretentive bioadhesive microsphere formulations and to devices for nasal delivery as well as for various mucosal routes. For example, chitosan-tripolyphosphate and chitosan± tripolyphosphate-chondroitin sulfate core-shell type microspheres were prepared by a continuous method using a multi-loop reactor under sterile conditions. All the types of microspheres produced were spherical in shape and had a porous structure; their mechanical resistance increased in the presence of chondroitin sulfate, which toughened the microsphere shell structure. For a drug release application, the preparation included the dissolution of ofloxacin, an antibiotic, in the chitosan solution before complex formation (Vodna et al., 2007). The study of the bioadhesive characteristics of chitosan led to the important discovery that this polysaccharide is not only bioadhesive so that it can be used to alter the intestinal transit of formulations and nasociliary clearance, but also has exceptional absorption effects when given nasally to rat and sheep models together with highly polar molecules such as insulin, calcitonin and morphine. The impressive increase in the bioavailability of the drugs administered together with chitosan could not be explained simply by a prolonged period of residence: it is now generally accepted that the mechanism of action of chitosan in enhancing the transport of drugs across the mucosal membranes is due to the combination of bioadhesion and the transient opening of the tight junctions between the cells of the mucosal membrane (Illum, 2003). Chitosan gels releasing insulin in response to glucose concentration have also been developed (Kashyap et al., 2007). For these purposes, chitosans can be formulated either as viscous solutions, as spray-dried powders, or as microspheres or nanoparticles. In most cases the effects of chitosan powders and microspheres are superior in providing enhancement of the nasal absorption of polar drugs as compared to chitosan solutions (nearly fivefold bioavailability of insulin, for instance). This may be justified by the formation of more effective hydrogels by spray-dried chitosans (see below). As a polar compound, morphine is not readily absorbed via the nose when administered in simple formulations (bioavailability in humans ca. 10%). A nasal chitosan morphine solution formulation can give rapid absorption of the


871

drug with the peak plasma concentration within 10 min and 60% bioavailability that can be optimised at 80%, offering patients rapid and efficient pain relief by a non-injectable route (Illum et al., 2002). Chitosan microparticles produced by emulsification, precipitation, complex coacervation or solvent evaporation are optionally stabilised by crosslinking or by polyelectrolyte complex formation. The drug is either encapsulated during production or absorbed into the particles after production. The freeze-drying techniques are generally preferred (Kas, 1997). For the production of chitosan nanoparticles, one may rely on the ability of chitosan to gel in contact with the negatively charged counterparts, for example tripolyphosphate ions. The definition of the experimental conditions for the formation of the chitosantripolyphosphate nanoparticles has been made by Pan et al. (2002). 31.7.1 Trans-dermal drug delivery The use of chitosan has great potential as an aid to trans-dermal drug delivery and has been shown to mediate trans-dermal drug availability. The reported widening of tight junctions by chitosan observed in Caco-2 cells in vitro may be partially responsible for the ability of chitosan to improve trans-dermal drug delivery. Tight junctions are dynamically regulated protein complexes that link adjacent epithelial cells in such a manner as to prevent the passage of molecules through the paracellular space. They are composed of known trans-membrane proteins (occludin and claudin) and several associated intracellular proteins (Tsukita et al., 2001). Tight junction integrity can be investigated in numerous ways including measuring the trans-epithelial electrical resistance across confluent Caco-2 monolayers. The quaternary derivatives of chitosan have been shown to have penetration enhancement properties because they open the tight junctions of the intestinal epithelia at neutral and alkaline pH values. The use of nanoparticulate systems has the advantage of protecting the peptidic drugs from the harsh environment of the gastrointestinal tract. Trimethyl chitosan and diethylmethyl chitosan, both with quaternisation degree of ca. 50%, were then used to prepare insulin nanoparticles with two different methods: ionotropic gelation and polyelectrolyte complexation. The latter nanoparticles had higher insulin loading efficiency and zeta potential than those made by ionotropic gelation. Trimethyl chitosan was also loaded with antigens for intranasal vaccination (Amidi et al., 2007). In vivo studies performed with trimethyl chitosans in rabbits confirmed the transdermal permeation enhancement, which increased with increasing degree of quaternisation (He et al., 2008). The polymers in free form had higher antibacterial activity against Gram-positive bacteria than in the nanoparticulate form (Sadeghi et al., 2008). Previous studies have shown chitosan-mediated decreases in electrical resistance of up to 80% across Caco-2 monolayers. This is accompanied by an increase in the permeability of the monolayers to inert hydrophilic protein

872


markers such as inulin or mannitol (Borchard et al., 1996; Dodane et al., 1999; Kotze et al., 1998; Ranaldi et al., 2002; DeBritto and Assis, 2007). A chitosanmediated increase in permeability to inert markers points to passive transport that is possible only through the paracellular space (Artursson et al., 1996). As the chitosan-mediated changes in resistance do not appear to be a result of cell toxicity, it is supposed to act through an effect on the barrier properties of the cellular tight junctions. Also quaternised chitosan has been studied extensively as an absorption enhancer and proved to be non-toxic, mucoadhesive and capable of opening the tight junctions between epithelial cells. Changing the chitosan concentration or increasing the number of crosslinks by using chitosan derivatives with branching side chains can modify the rate of release of drug from these formulations. Once applied, the chitosan present in this formulation mediates prolonged contact with the epithelium via electrostatic interaction of the positively charged chitosan and the negatively charged glycoprotein residues on the cell surface. Passive diffusion of the drug down its concentration gradient onto the underlying epithelium over a prolonged period results in absorption of drug (Park et al., 2000; Ramanathan and Block, 2001). There are several advantages of trans-dermal drug delivery as opposed to oral delivery. For example, trans-dermally delivered drugs avoid the hostile environment of the gastrointestinal tract (hydrochloric acid and enzymes), and avoid first pass metabolism (the skin empties into the venous circulation and the drug is not routed directly through the liver where much drug metabolism occurs as with orally applied drugs). In addition, drugs delivered by the trans-dermal route show sustained plasma profiles over long periods of time, thus minimising the risk of fluctuations of drug plasma levels at night or between oral doses. Other attractive features lead to better patient compliance. The most popular and commercially available trans-dermal drug delivery system is the nicotine patch for nicotine replacement during smoking cessation. Chitosan gel-mediated trans-dermal drug permeation may be enhanced by the simultaneous application of other technologies known to aid trans-dermal drug delivery. The application of an electric current to aid the passage of drugs across the epithelium, along with dermal application of chitosan-drug hydrogels, resulted in a greater drug flux across the skin barrier compared to either method individually. This represents an enormous increase in the amount of permeated drug across the usually impermeable skin. 31.7.2 Spray-drying As a drug carrier, chitosan offers certain advantages over other polymers, such as cationicity, bioadhesion via interaction with mucin, degradability by lysozyme and lipases, generation of safe oligomers and monomers (glucosamine and N-acetylglucosamine), absence of allergic reactions, and immunostimulating activity. Chitosan helps overcome insolubility and hydrophobicity of drugs, but the semi-crystalline powder does not lend itself to direct compression; however, amorphous chitosan microspheres obtained by spray-drying


873

are free-flowing and compressible powders, most suitable for drug delivery (He et al., 1999; Rege et al., 1999, 2003; DeLaTorre et al., 2003; Huang et al., 2003; Muzzarelli et al., 2004). Spray-drying of chitosan salt solutions provides chitosan microspheres having diameters close to 2±5 micron and improved binding functionality. While chitosan was often spray-dried, the following are significant examples. Betamethasone disodium phosphate-loaded microspheres demonstrated good drug stability (less 1% hydrolysis product), high entrapped efficiency (95%) and positive surface charge (37.5 mV). Formulation factors were correlated to particulate characteristics for optimising the pulmonary delivery. The betamethasone release rates were influenced by the drug/polymer ratio in the manner that an increase in the release percentage and burst release percentage was observed when the drug loading was decreased. The in vitro release of betamethasone showed a dose-dependent burst followed by a slower release phase that was proportional to the drug concentration in the range 14±44% w/w (Huang et al., 2002). Chitosan microspheres containing chlorhexidine diacetate, an antiseptic, were prepared by spray-drying. Chlorhexidine from the chitosan microspheres dissolved more quickly in vitro than chlorhexidine powder. The minimum inhibitory concentration, minimum bacterial concentration and killing time showed that the loading of chlorhexidine into chitosan could maintain or improve the anti-microbial activity of the drug, the improvement being particularly high against Candida albicans. It should be noted that the drug did not decompose despite its thermal lability above 70 ëC. An inclusion complex composed of progesterone and hydroxypropyl- cyclodextrin was prepared by spray-drying and freeze-drying methods. Progesterone alone and its inclusion complex with hydroxypropyl- -cyclodextrin were incorporated into chitosan by spray-drying and freeze-drying. Release data showed significant improvement of the dissolution rate of progesterone and controlled release was obtained in the presence of chitosan (Cerchiara et al., 2003). 31.7.3 Pulmonary drug delivery Chitosan is able to enhance the surface activity of 0.5 mg/ml of bovine lipid extract surfactant and to resist albumin-induced inactivation at an extremely low concentration of 0.05 mg/ml, one thousand times smaller than the usual concentration of poly(etylene glycol) and 20 times smaller than for hyaluronan (Zuo et al., 2006). Learoyd et al. (2008) described the preparation of highly dispersible dry powders for pulmonary delivery that display sustained drug release characteristics; they were prepared by spray-drying 30% aqueous ethanol formulations containing terbutaline sulfate as a model drug, chitosan as a drug release modifier, and leucine as an aerosolisation enhancer. The aerosol properties of the spray-dried powders were investigated. By selecting the average molecular

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weight of chitosan it was possible to exert some control over the rate of drug release: upon increasing the molecular weight of chitosan a more sustained release profile was obtained. For example, the low molecular weight chitosan released the totality of terbutaline after 30 min, whereas the high molecular weight chitosan required 2 h. Of course, the in vitro dissolution tests of this nature do not take into consideration the environment that would be encountered following inhalation, such as the relatively low quantity of lung secretions, the large surface area, the lungs' clearing mechanism such as the mucociliary escalator and the mucus layer and the presence of lung surfactant. The powders are expected to deposit predominantly in the central and peripheral regions of the lung following inhalation, with minimal oropharyngeal concurrent deposition. By virtue of their hydrogel behaviour in the lung, these powders would display delayed rather than instantaneous drug release thus offering the opportunity to reduce dosing frequency. Ventura et al. (2008) incorporated moxifloxacin, a wide spectrum antimicrobial active against common respiratory pathogens, in spray-dried chitosan microspheres, and observed that its intrapulmonary concentration was superior to that generated in plasma. By this means, they could overcome the common adverse events associated with the oral administration of this drug such as nausea and diarrhoea due to the impact on the human intestinal microflora. Uncrosslinked microspheres rapidly swelled in the lungs and released some chitosan that altered the biomembrane permeability to the drug. Glutaraldehydecrosslinked microspheres, on the other hand, did not exhibit this property. Therefore the microspheres retarded the absorption of moxifloxacin, and within 6 h the cumulative amount of permeated drug was ca. 18, 11 and 7% w/w for free drug, loaded crosslinked microspheres, and loaded uncrosslinked microspheres, respectively. Microspheres of methylpyrrolidinone chitosan, a modified chitosan amply recognised as one of the least cytotoxic materials, was found suitable for the intranasal delivery of metoclopramide HCl (Giunchedi et al., 2002). In their further study (Gavini et al., 2008) attention was devoted to the hydrogel formation from methylpyrrolidinone chitosan. The microspheres obtained by spray-drying were contacted with buffer solutions: when HCl/KCl or acetate buffers are used, gel forms and then dissolves upon dilution with water. However, when phosphate buffers are used, a hydrogel forms which does not dissolve in water regardless of the amount used, but dissolves in diluted HCl solutions. Hydrogel formation is therefore dependent on the medium, but not on the presence of a drug. The phosphate anion at pH values 5.5±7.4 seems to bridge the chitosan chains leading to the formation of an ionically interconnected hydrogel. Because methylpyrrolidinone chitosan microspheres retain adhesion properties and lend themselves to incorporation of a variety of drugs, it appears that they are most suitable for biomedical applications involving drug delivery.


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31.7.4 Drug delivery to the intestine Neutron activation-based gamma scintigraphy was used to evaluate the gastroretentive properties of formulations containing chitosan (Mw 150 kDa) in humans. At the same time, the transit of the formulations (40 or 95% of chitosan) was monitored in the small intestine: although the chitosan studied had exhibited marked mucoadhesive capacities in vitro, retention of the chitosan formulations in the upper gastrointestinal tract was not sufficiently reproducible and the duration of retention was relatively short (Sakkinen et al., 2006). Therefore, chitosan tablets should be protected with an enteric coating or similar, if they are expected to reach the lower intestine without damage. In this light, there is interest in preparing chitosan-Ca-alginate microparticles that can effectively deliver 5-aminosalicylic acid (5ASA) to the colon after per os administration. A solution containing 5ASA and sodium alginate was spraydried to obtain microspheres smaller than 10 m, that were crosslinked and coated into a solution of CaCl2 and chitosan. Of importance, 1H NMR and UVvis spectra of 5ASA showed no degradation when working under light protection with freshly prepared solution, and using nitrogen to prevent the oxidative self-coupling of 5ASA moieties. The microspheres showed acceptable morphology, and prevailing localisation of chitosan in the particle wall, while alginate was homogeneously distributed throughout the particle imparting anionic character. The IR spectra of 5ASA-loaded Ca alginate microparticles indicated absence of covalent bonds between the polymer and the drug that was molecularly dispersed within the chitosan alginate microspheres during the production process (Mladenovska et al., 2007). Chitosan alginate nanoparticles were investigated as mucoadhesive vehicle for the prolonged topical ophthalmic delivery of an antibiotic, gatifloxacin. A modified coacervation or ionotropic gelation method was used to produce gatifloxacin-loaded nanoparticles with average particle size 205±572 nm and zeta potential 17.6±47.8 mV (Motwani et al., 2008). A combination of spray-dried chitosan acetate and hydroxymethylpropyl cellulose was tested as a new compression coat for 5ASA tablets. In a simulated system, such tablets were able to pass through the stomach, pH 1.0, and the small intestine, pH 6.8. The delayed release was controlled owing to the swelling with gradual dissolution of chitosan and modified cellulose at low pH and depressed solubility at neutral pH. After reaching the colon, the dissolution of chitosan triggered the 90% drug release within 14 hours. Moreover, the chitosan was found to undergo degradation by unspecific activity of -glucosidase in the colonic fluid thus enhancing the drug release (Nunthanid et al., 2008). Because the chitosan powder can be easily compressed into a tablet, it was demonstrated that 5ASA can be admixed with the plain chitosan powder and the resulting tablet can be coated with convenient enteric coatings: the antiinflammatory action of chitosan enhances the curative properties of 5ASA while being degraded by enzymes provided by the colonic flora (Muzzarelli, 2005). Following a more traditional approach, chitosan hydrogel beads were prepared by the crosslinking method followed by enteric coating with

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EudragitÕS100. The size of the beads was ca. 1:04 0:82 mm. The amount of the drug released after 24 h from the formulation was ca. 97% in the presence of extracellular enzymes as compared with ca. 64% and 96% release of drug after 3 and 6 days of enzyme induction, respectively, in the presence of 4% cecal content (Jain et al., 2007). Uncoated and EudragitÕ-coated chitosan-Ca alginate microparticles efficiently loaded with budesonide, with bioadhesive and controlled release properties in the gastrointestinal tract, were prepared by spray-drying. Microspheres had mean size 4.05±5.36 m, narrow unimodal distribution and positive surface charge. CaCl2 limited the swelling ratio, while the swelling behaviour of coated beads was mainly determined by the EudragitÕ enteric coating. The controlled release properties were suitable for local treatment of inflammatory bowel diseases (Crcarevska et al., 2008). The water-soluble N-(2-carboxybenzyl)chitosan (Muzzarelli et al., 1982) was crosslinked with glutaraldehyde and its swelling characteristics were studied in different pH buffer solutions. The swelling ratio decreased with an increase in the amount of glutaraldehyde, and the swelling was more evident in alkaline solutions than in acidic media, showing the lowest swelling ratio at pH 5.0. The latter increased in alkaline solutions with the raising of the degree of substitution, but no significant change was observed in an acidic environment. The crosslinked carboxybenzyl chitosan showed swelling reversibility when alternately soaked in pH 1.0 and 7.4 buffer solutions. Results qualified the crosslinked carboxybenzyl chitosan as a potential pH-sensitive carrier for colonspecific drug delivery system (Lin et al., 2007).

31.8

Conclusion

The good performance of chitosan itself and its derivatives in the dietary food area and in the pharmaceutical area, accompanied by the more thorough understanding of the chemistry of chitosan-based gels, support the expectation that chitosan gels will expand their current range of applications in the near future. This versatile biopolymer, remarkable for its cationicity, has attained a unique position among the hydrocolloids.

31.9

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32 Konjac mannan S. Takigami, Gunma University, Japan

Abstract: Konjac mannan is a main component of tubers of konjac which is a perennial plant of Araceae. It is a heteropolysaccharide consisting of -Dglucose (G) and -D-mannose (M), with a G/M ratio of 1 to 1.6. Konjac mannan contains very small amounts of acetyl groups and the viscosity of its aqueous solution is quite high. Deacetylation occurs with alkali treatment and a chewy irreversible gel is prepared. The gel has been used as a traditional dietary food in Japan for a long time. Konjac mannan interacts synergistically with other polysaccharides and forms thermoreversible gels. In this chapter, the following subjects are explained: cultivation of the konjac tuber, the production process and purification of konjac flour, the chemical structure and molecular weight of konjac mannan, the component analysis of commercial konjac flour, the properties of mixture gel synergistically prepared by konjac mannan and other polysaccharides, the uses and applications of konjac flour, and regulatory status. Key words: konjac mannan, glucomannan, konjac tuber, cultivation, production process, purification, structure, gel, viscosity.

32.1

Introduction

Konjac (Lasioideae Amorphophallus) is a perennial plant and a member of the family of Araceae. The original home of the konjac plant is not certain, but is considered to be in Southeast Asia. There are many species of konjac plants in the Far East and Southeast Asia that belong to the Amorphophallus,1 for example, A. konjac C. Koch (Japan, China, Indonesia), A. bulbifer Bl. (Indonesia), A. oncophyllus Prain ex Hook. f. (Indonesia), A. variabilis Blume (the Philippines, Indonesia, Malaysia), etc. Only Amorphophallus konjac C. Koch grows in Japan. They contain konjac mannan in their tubers. Konjac

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Fig. 32.1

Konjac plants.

mannan is a heteropolysaccharide consisting of -D-glucose (G) and -Dmannose (M), with a G/M ratio of 1 to 1.6. The konjac tuber grows in size year by year and three- to five-year-old plants bloom with purplish-red flowers in the spring. Konjac is an allogamous plant and plant breeding is performed by crossfertilisation. Figures 32.1 and 32.2 show konjac plants and tubers. The main component of the konjac tuber is konjac mannan (KM), which varies in composition from 8±10% of a raw tuber. Starch, lipid and minerals are also present in the tuber. KM is accumulated in egg-shaped cells covered with scale-like cell walls2, 3 and the KM cells are observed within the parenchyma of the tuber. The size and number of the KM cells increase with distance from the epidermis, reaching ~650 m at the central part of the tuber. Other types of organelles in the parenchyma surround the KM cells. Starch exists in spherical organelles as small particles. Bunches of needle-like crystals are also observed in the tuber and the size of a crystal is ca. 150 m 5 m. Since a high content of calcium was detected in the crystal by energy dispersive X-ray (EDX) analysis, the needle-like crystal is considered to be calcium oxalate. The konjac

Konjac mannan 891

Fig. 32.2

Two-year-old konjac tubers.

tuber, unprocessed, has a harsh taste. This can be removed from the konjac flour by processing. Irreversible konjac mannan gel is prepared by alkali treatment of grated konjac tuber or konjac flour aqueous solution. KM has very small amount of acetyl groups and deacetylation occurs with the alkali treatment.4 It is considered that the gelation of konjac mannan is induced by deacetylation. The lowest critical concentration of konjac flour aqueous solution necessary for gel formation is about 0.5%. The konjac gel (Kon-nyaku in Japanese) is classified as a dietary fibre and it has a chewy texture. The first description of konjac gel and its preparation process are found in an old Chinese poem composed by Zuo Shi and its annotation written in the third century.5 It is thought in Japan that the production method of konjac gel was introduced from Korea with Buddhism in the sixth century as a medicine. However, it took a long time before konjac gel became a popular food and this was due to two important investigations for the production process of konjac flour. T. Nakajima (1745±1826) developed a manufacturing technique to produce konjac flour by pulverising dried chips of konjac tuber (Arako). K. Mashiko (1745±1854) improved on this technique to obtain cleaner konjac flour (Seiko). He polished Arako using a mortar worked by a water wheel and separated impurities from the konjac flour by wind sifting. Nowadays, konjac flour is produced in very modern factories controlled by computer systems. However, the principle of the production manufacturing process is the same. It is well known that konjac mannan interacts synergistically with kappa carrageenan6 and xanthan gum7, 8 and forms elastic thermoreversible gels. These synergistic gels are major products in the food industry as new healthy gel foods,

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particularly in Japan. In the United States, the US Department of Agriculture recently accepted the use of konjac flour as a binder in meat and poultry products. Konjac flour is suitable for thickening, gelling, texturing, and water binding. It may be used to provide fat-replacement properties in fat-free and low-fat meat products.

32.2

Manufacture

32.2.1 Cultivation Only Amorphophallus konjac C. Koch grows in Japan and selective breeding of konjac plants has been carried out. Recently, five species of the A. konjac have been cultivated, namely, Zairai, Shina, Haruna-kuro, Akagi-ohdama and Miyogi-yutaka. The latter three species are improved breeds and Haruna-kuro and Akagi-ohdama account for more than 90% of the total tuber output. The cultivation process of the konjac tuber in Japan is as follows. Seed tubers (Kigo) and/or one-year-old tubers are planted in the spring. The tubers push out new shoots and are consumed completely. The konjac plants grow during the summer and have new tubers. In the late autumn, the plants die and new tubers are dug from the ground. The new tuber has seed tubers at the top of its suckers. The two-year-old tubers are used to produce konjac flour. One-year-old tubers and the seed tubers are kept in a storehouse with heating during the winter to avoid freezing. This cycle is repeated in the following spring. In China, there are six kinds of konjac plants containing konjac mannan and two species can be cultivated, namely, A. rivieri Duieu and A. aldus Lie et Chen. The selective breeding of konjac plants is also actively carried out. 32.2.2 Production process of konjac flour The two-year-old konjac tubers are brought to a storehouse in containers from farmhouses. The tubers are transported to a washing apparatus using conveyer belts and are washed with water, brushing away mud and epidermis and then distributed to each line. The washed konjac tubers are sliced into thin chips, and the chips are dried in a hot-air drier equipped with a heavy oil burner. This is because konjac flour contains a small amount of sulphur dioxide as an impurity. Sulphur dioxide bleaches konjac chips and for this reason the colour of lowerquality konjac flour is extremely white. The dried konjac chips are called Arako in Japanese. The dried chips are pulverised and konjac mannan (KM) particles (i.e., konjac flour) are obtained. Since the KM particles are very tough, they are polished after being produced to remove impurities surrounding the KM cells. Then konjac flour is separated by wind shifting. The polished konjac flour is called Seiko. Micro-fine powder obtained as a by-product is collected using a dust collector. The by-product is called Tobiko in Japanese, which literally means flying powder. The main components of Tobiko are starch and fine KM powder. Protein (ca. 24%) and ash (ca. 10%) are also included in Tobiko.

Konjac mannan 893 The viscosity of konjac flour is dependent on the raw tubers and is controlled by the mixing of flours produced from different types of tubers. Then the konjac flour thus prepared is packed into the bags and is kept in a cool storehouse to avoid a change in quality. 32.2.3 Purification of konjac flour Commercial konjac flour (Seiko) is a light-coloured powder with fish-like smell and a slightly harsh taste. The current practice of several companies is to wash konjac flour with ethanol aqueous solution to remove the micro-fine powders remaining on the surface and the impurities trapped inside the konjac particles. The konjac flour is whitened by washing. Figures 32.3 and 32.4 show the SEM images of commercial konjac flour, with Fig. 32.4 being the one which has been highly purified. The surface of konjac flour shows scale-like patterns and seems to have been worn smooth (Fig. 32.3). After purification, the scale-like patterns are more clearly observed. Table 32.1 shows the composition of the various components in konjac flour before and after purification. Since the protein content was determined by nitrogen analysis, the value represents not only protein but also all nitrogencontaining substances. The carbohydrate content increased with washing but the concentration of the other components decreased by washing. The carbohydrate value parallels that of KM. The fish-like smell decreases remarkably by washing. It has been reported that alkali treated konjac gel contains trimethylamine and that the fish-like smell of the flour is caused by the amine.9, 10 Konjac flour with and without

Fig. 32.3 Scanning electron micrograph of konjac flour (Seiko).

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Fig. 32.4 Table 32.1 purification

Scanning electron micrograph of purified konjac flour.

Analytical results of components in konjac flour before and after Contents (g/100g of sample)

Konjac flour Purified konjac flour

Water

Protein

Lipid

Carbohydrate

Fibre

Ash

7.2 7.5

2.2 0.8

2.3 0.9

82.6 88.6

0.5 0.5

5.2 1.7

purification showed mass spectra attributable to nitrogen-containing substances, but they were not identical to trimethylamine.2 This demonstrates that konjac flour does not contain trimethylamine as an impurity. Trimethylamine should be separated from other nitrogen-containing substances by the alkali treatment. The purification of konjac flour is very effective in preventing the putrefaction of konjac gel prepared by alkali treatment and the syneresis of the mixed gels prepared by konjac mannan and other gums.

32.3

Structure

The main component of konjac flour is a glucomannan called konjac mannan (KM), whose main chain consists of D-glucose and D-mannose linked by -D-1,4 bonds. The ratio of glucose (G) to mannose (M) is reported to be 1 to 1.611±13 or 2 to 3.14, 15 Although the repeating structural unit of the main chain is still uncertain, typical proposals for the unit by research scientists are as follows:

Konjac mannan 895 1. 2. 3.

G-G-M-M-M-M-G-M or G-G-M-G-M-M-M-M11 M-M-M-G-G13 G-G-M-M-G-M-M-M-M-M-G-G-M.13, 16

It is also reported that KM has side chains and the branching position is considered to be the C3 position of mannose residues11, 17 or C3 positions on both glucose and mannose13 in the main chain. The degree of branching is estimated at approximately three for every 32 sugar units14 or at one for 80 sugar residues.11 The length of the branched chain was also evaluated as 11 to 16 hexose residues17 or as several hexose units.11 KM contains acetyl groups in the main chain. Figure 32.5 shows a Fourier transformation infra-red (FT-IR) spectrum of purified KM. An absorption due to stretching vibration of C = O group in acetyl group is observed at 1730 cmÿ1. The acetyl group content was estimated at one for 19 sugar residues.4 Figure 32.6 shows the chemical structure of KM proposed by Okimasu.1, 18 The crystalline form of KM was studied by the X-ray diffraction method.19 KM shows a different X-ray diffraction powder pattern from both crystalline polymorphs of other glucomannans (mannan I and mannan II) which have been studied. The fibre pattern of the annealed KM indicated that it exists in an extended two-fold helical structure. Since konjac flour forms very viscous solutions, measurement of the weight average molecular weight (Mw) and the mean square radius of gyration (<S2>1/2) of KM was carried out using partially methylated KM samples.20 The average values of Mw and <S2>1/2 were determined to be 10105 and 110nm. It was also reported that both Mw and <S2>1/2 were found to be dependent on species of konjac plant, cultivation districts and preparation method. The authors21 measured molecular weight (Mw), molecular dispersity and root mean square (RMS) of KM (Akagi ohdama species obtained in Gunma prefecture, Japan) using the Dawn multi-angle laser light scattering method, associated with a gel permeation

Fig. 32.5 FT-IR spectrum of konjac mannan analysed by the attenuated total reflection (ATR) method.

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Fig. 32.6

Chemical structure of konjac mannan.

chromatographic (GPC) fractionation. The Mw, molecular dispersity and RMS were 13.2105, 2.1 and 130nm, respectively.

32.4

Technical data

The quality of commercial konjac flour is appraised by the size of KM particles, viscosity, whiteness, moisture and admixing of impurities such as pieces of scorched epidermis and denatured KM particles during the hot-air drying. Some kinds of bacteria are observed in konjac flour but these are not colon bacilli.22 They cause putrefaction of konjac gel and degradation of molecular weight of konjac mannan. The most important criterion of the quality of konjac flour is its high viscosity in aqueous solution, which in turn depends on the molecular weight of the polysaccharide. Table 32.2 shows typical technical data of two types of commercial konjac flours and purified flour of them. The data is kindly given by Ogino Shoten Co. Ltd. in Gunma Prefecture, Japan. The Chinese konjac flour is a bonded one and was pulverised by Ogino Shoten Co. Ltd. Konjac mannan is a water-soluble polymer but it needs a special technique to dissolve it in water completely. To dissolve at room temperature, konjac flour must be added to water with stirring until the powder is completely dissolved. It is important to stir the solution continuously so that the powder does not lump. Hot water is not effective to dissolve konjac flour. The relationship between viscosity of purified commercial konjac flour and stirring time is shown in Fig. 32.7. The konjac flour, Rheolex RS, was characterised by a very fine mesh size (80 mesh sieve) and the measurements were carried out at 25 ëC using a viscometer. The data was kindly provided by the Shimizu Chemical Co. Ltd. in Hiroshima Prefecture, Japan. The viscosity of KM aqueous solution increases with stirring time and reaches a constant value after two hours. The viscosity of KM aqueous solution increases gradually with increasing concentration until 1% and then increases remarkably. As seen in Fig. 32.7, the viscosity of a 2% aqueous solution is more than 12 times higher than that of 1% solution. The viscosity of KM aqueous solution is not affected by salt

Konjac mannan 897 Table 32.2

Analytical results of components in commercial konjac flours Japanese konjac tuber

Viscosity (mPas)+ Whiteness Water* Protein* Lipid* Carbohydrate* Fibre* Ash* Sulphur dioxide Arsenic* Lead* Trimethyl amine** Number of germ Coliform bacteria

Ordinary flour

Purified flour

15.0±15.2 66±68 6.5 2.1 1.3 84.6 0.5 5.0 0.65 g/kg Not detected Not detected 490 ppm Less than 300/g negative

17.0±18.0 73 6.6 1.1 0.3 89.2 0.6 2.2 0.17 g/kg Not detected Not detected 85 ppm Less than 300/g negative

Chinese konjac tuber (bonded) Ordinary flour

Purified flour

13.5±13.6 18.0 69.9 68.9 8.4 5.3 3.0 1.5 0.9 0.3 82.2 90.0 0.6 0.8 4.9 2.1 2.1 g/kg 0.64 g/kg Not detected Not detected Not detected Not detected 760 ppm 170 ppm 420/g Less than 300/g negative negative

+ 1% konjac aqueous solution at 35 ëC after 4 h stirring at 90 rpm. * g/100 g of konjac flour. ** nitrogen-containing substances.

concentration, but is affected by pH of the solution. The effect of pH on viscosity change for 1% and 2% KM solutions is listed in Table 32.3. The viscosity of KM solution decreases with decreasing pH value. At a high pH, KM solution changes to gel.

Fig. 32.7 Relationships between viscosity of purified commercial konjac flour, Rheolex RS, and stirring time: () 1%, (·) 2%.

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Table 32.3

Effect of pH on viscosity change for 1% and 2% KM solutions Viscosity (cps)

KM* concentration Water (%) (no pH adjust.) 1 2

31,600 341,000

pH 4

pH 3

pH 2.5

31,800 340,000

29,900 301,000

18,600 251,000

* ± Rheolex RS.

Table 32.4 Viscosity of mixtures of KM and other gums with various composition. Total concentration of the mixtures is 1% KM* Other gums concentration concentration (%) (%) 0.0 0.2 0.4 0.6 0.8 1.0

1.0 0.8 0.6 0.4 0.2 0.0

Viscosity (cps) Xan

LBG

Gel

Pec

Car

Aga

8,250 225 0 0 300 0 8,800 650 125 75 12,750 60 12,000 2,700 1,525 600 17,500 725 13,250 7,500 5,860 3,750 51,000 3,740 161,000 15,750 14,700 11,640 113,600 12,500 29,500 29,500 29,500 29,500 29,500 29,500

GG

CMC

4,250 75 6,800 225 10,000 1,065 14,750 4,075 20,750 12,200 29,500 29,500

* ± Rheolex RS; Xan ± xanthan gum; LBG ± Locust bean gum; Gel ± Gelatin; Pec ± Pectin; Car ± carrageenan; Aga ± Agar; GG ± Guar gum; CMC ± Carboxymethyl cellulose.

Table 32.5 Gel strength of mixtures of KM and other gums with various compositions. Total concentration of the mixtures is 1% KM* Other gums concentration concentration (%) (%) 0.0 0.2 0.4 0.6 0.8 1.0

1.0 0.8 0.6 0.4 0.2 0.0

Gel strength (g) Xan

LBG

Gel

Pec

Car

Aga

GG

CMC

± 7.8 161.7 84.3 34.7 ±

± ± ± ± ± ±

± ± ± ± ± ±

± ± ± ± ± ±

24.1 118.7 185.3 129.0 ± ±

21.4 25.7 20.3 11.7 4.0 ±

± ± ± ± ± ±

± ± ± ± ± Ð

* ± Rheolex RS; Xan ± xanthan gum; LBG ± Locust bean gum; Gel ± Gelatin; Pec ± Pectin; Car ± carrageenan; Aga ± Agar; GG ± Guar gum; CMC ± Carboxymethyl cellulose.

Konjac mannan interacts synergistically with other polysaccharides and forms thermoreversible gels. The viscosity of the mixtures and the gel strength are listed in Tables 32.4 and 32.5, respectively. The synergism is observed for the combination of KM and xanthan gum, KM and carrageenan, and KM and agar. Table 32.6 shows the effect of sugar concentration on the gel strength for 1% mixed gel with various ratios of KM to -carrageenan. The addition of sugar

Konjac mannan 899 Table 32.6 Effect of sugar concentration on gel strength of mixed gel of KM and carrageenan with various compositions. Total concentration of the mixtures is 1% Gel strength (g) *

KM /Car ratio 8:2 7:3 6:4 5:5 4:6 3:7 2:8

Sugar concentration (%) 0

5

10

15

± ± 121.5 331.0 299.7 216.8 137.5

± 141.6 205.4 275.3 285.2 213.8 100.1

± 134.9 195.8 299.1 297.4 187.8 100.3

± 145.3 220.7 260.9 222.4 101.1 109.7

* ± Rheolex RS; Car ± -carrageenan. Table 32.7 Effect of salt concentration on gel strength of mixed gel of KM and carrageenan with various compositions. Total concentration of the mixtures is 1% Gel strength (g) *

KM /Car ratio 8:2 7:3 6:4 5:5 4:6 3:7 2:8

Salt concentration (%) 0

1

3

5

± ± 121.5 331.0 299.7 216.8 137.5

41.0 72.0 120.7 247.7 342.2 529.0 265.4

± ± ± ± 27.9 87.5 126.5

± ± ± ± ± ± ±

* ± Rheolex RS; Car ± -carrageenan.

enhances the gel strength slightly for the gel with higher composition of KM but reduces the strength for the gel with lower composition of KM. Table 32.7 shows the influence of the addition of salt on the gel formation for a 1% of mixture of KM and -carrageenan. The synergistic gel formation is inhibited by addition of salt.

32.5


Konjac flour has been used as an important food ingredient for more than a thousand years. With the addition of a mild alkali such as calcium hydroxide, konjac flour aqueous solution (ca. 3% of concentration) changes to a strong, elastic and irreversible gel. The alkali treated konjac gel is quite a popular traditional Japanese food and is called Kon-nyaku in Japanese. Recently,

900


Table 32.8

Applications and functional uses of konjac mannan

Application

Function

Confectionery Jelly Yoghurt Pudding Pasta Beverage Meat Edible film

Viscosity, texture improver, moisture enhancer Gel strength, texture improver Fruit suspension, viscosity, gelation Thickening, mouthfeel Water-holding capacity Fibre content, mouthfeel Bulking, fat replacer, moisture enhancer Water soluble, water insoluble

synergistic gels prepared by mixing of other hydrocolloids are major products in the food industry as new types of healthy jellies. Clinical studies indicate that konjac mannan solution has the ability to reduce serum cholesterol and serum triglyceride. Konjac mannan also has an influence on glucose tolerance and glucose absorption. However, the alkali treated gel food does not have such effects. Konjac flour is suitable for thickening, gelling, texturing, and water binding. It may be used to provide fat replacement properties in fat-free and low-fat meat products. Applications and functional uses of konjac mannan are listed in Table 32.8.

32.6

Regulatory status

In Japan, konjac flour is accepted as a food ingredient and a food additive for thickening and as a stabiliser according to the provisions of the Food Sanitation Act. For regulatory purposes, a distinction must be drawn between konjac flour and konjac mannan, the separated polysaccharide. The Food Chemical Codex lists the current uses of konjac flour in the United States as gelling agent, thickener, film former, emulsifier, and stabiliser. Konjac flour is also used as a binder in meat and poultry products. Konjac mannan has been recognised as GRAS (generally recognised as safe) by the Food and Drug Administration (FDA) since 1994 and the US Department of Agriculture (USDA) accepted the use of konjac flour as a binder in meat and poultry products in 1996. In Sweden, it was recognised that konjac mannan has the ability to reduce serum cholesterol and indication of the effect was officially accepted enabling claims to be made for its use as a functional food. Konjac flour imported into Europe for diet food and pet food is rarely of consistent quality and does not meet EU standards. However, konjac mannan received a provisional European classification number as a food additive (E425) in 1998. Konjac mannan can thus be imported into Europe because it has achieved an E number.

Konjac mannan 901

32.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22.

References

(ed.), Science of Konjac, Keisuisha, Hiroshima (1984). and G. O. PHILLIPS Gums and Stabilisers for the Food Industry, 8, 391 (1996), (eds G. O. Phillips, P. A. Williams and D. J. Wedlock), IRL Press, Oxford, UK. S. TAKIGAMI, T. TAKIGUCHI and G. O. PHILLIPS Food Hydrocolloids, 11, 479 (1997). K. MAEKAJI Agric. Biol. Chem., 38, 315 (1974). S. OKIMASU (ed.) (1984) Science of Konjac, Keisuisha, Hiroshima, Japan. P. A. WILLIAMS, S. M. CLEGG, M. J. LANGDON, K. NISHINARI and G. O. PHILLIPS Gums and Stabilisers for the Food Industry, 6, 209 (1992), (Eds. G. O. Phillips, P. A. Williams and D. J. Wedlock), IRL Press, Oxford, UK. G. J. BROWNSEY, P. CAIRNS, M. J. MILES and V. J. MORRIS Carbohydr. Research, 176, 329 (1988). P. A. WILLIAMS, D. H. DAY, K. NISHINARI and G. O. PHILLIPS Food Hydrocolloids, 4, 489 (1991). T. KASAI and Y. KOBATA Proceeding of Hokkaido University, 5, 145 (1965). N. KIMURA, K. MOTOKI, T. TAKIGUCHI and Y. SATOU Annual Report of Gunmaken Industrial Research Laboratory (1994), p. 147, Gunma, Japan. K. KATO and K. MATSUDA Agric. Biol. Chem., 33, 1446 (1969). H. SHIMAHARA, H. SUZUKI, N. SUGIYAMA and K. NISHIDA Agric. Biol. Chem., 39, 301 (1975). M. MAEDA, H. SHIMAHARA and N. SUGIYAMA Agric. Biol. Chem., 44, 245 (1980). F. SMITH and C. SRIVASTA J. Am. Chem. Soc., 81, 1715 (1959). T. SATO, A. MORIYA, J. MIZUKUCHI and S. SUZUKI Nippon Kagaku Zasshi, 91, 1071 (1970). R. TAKAHASHI, I. KUSUKABE, S. KUSANO, Y. SAKURAI, K. MURAKAMI, A. MAEKAWA and T. SUZUKI Agric. Biol. Chem., 48, 2943 (1984). T. NAKAJIMA and K. MAEKAWA Matsuyama Shinonome Gakuen Kenkyuronshu, 2, 55 (1966); 3, 117 (1967). S. OKIMASU and N. KISHIDA Hiroshima Joshi Daigaku, Kaseigakubu Kiyo, 13, 1 (1982). K. OGAWA, T. YUI and T. MIZUNO Agric. Biol. Chem., 55, 2105 (1991). N. KISHIDA, S. OKIMASU and T. KAMATA Agric. Biol. Chem., 42, 1645 (1978). Unpublished data. T. TAKIGUCHI, T. NARITA, K. SEKIGUCHI, I. YOSHINO and I. KAWANO Annual Report of Gunmaken Industrial Research Laboratory (1990), p. 168, Gunma, Japan. S. OKIMASU

S. TAKIGAMI

INDEX

Index Terms

Links

A A. xylinum BPR2001

725

A. xylinum BPR3001E

725

Absidia coerulea

853

Acacia senegal

253

726

258

260

258

260

702 amino acid composition

261

carbohydrate component of gum

263

characteristics

261

collecting gum arabic

253

molecular mass distribution

262

Acacia seyal

253

amino acid composition

261

characteristics

261


262

Acacia seyal var. fistula

255

Acacia seyal var. seyal

255

Acetobacter xylinum

725

acidic mammalian chitinase

861

728

actigum, see Scleroglucan Aerobacter levanicum

603

affinity chromatography

314

afzelia africana

539

agar

540

541

82 agarophyte seaweed for production use

84

This page has been reformatted by Knovel to provide easier navigation.

477

Index Terms

Links

agar (Cont.) applications

96

cultural world regions

99

different uses and agarophytes used

97

food applications

96

industrial application

103

insect culture

102

microorganism culture media

103

vegetable tissue culture formulations

102

chemical structure

89

agarose

90

future trends

104

easily soluble agar comparative analysis gelation

105 91

agarose gelation

94

gelling and melting temperatures

93

typical gel temperatures

93

historical background

83

manufacture

86

freezing-thawing method

87

syneresis method

87

Agaricus bisporus

857

agarobioses

88

agaropectins

91

agarophyte seaweed

84

Gelidium sesquipedale microphotograph taxonomic classification α-L-arabinofuranosyl

86 85 654

664


Index Terms

Links

Albumen, see egg white albumin

391

Alcalase

658

Alcaligenes faecalis var. myxogenes

568

alcohol

194

aldobiouronic acid

480

alginates

807

composition and sequential parameters

811

foods, nutrition and health

823

applications in food products

394

823

nutritional aspects and health benefits

823

future trends

824

gels and gelling technologies

817

alginic acid gels

822

diffusion setting

819

elastic properties as function of average G-block length

820

internal setting

821

ionic crosslinking

818

parameters controlling kinetics and final properties principal methods of manufacturing

817 819

isolation from seaweeds

809

manufacture

808

regulatory status

824

structural characteristics

810

structure and physical properties

809

chemical composition and sequence

809

molecular weight

812


Index Terms

Links

alginates (Cont.) selective binding ions

812

source dependence

811

technical data limitations for use

813 813

properties and applications in liquid phase

816

alginic acid gel

813

alkalimetric titration

853

alkanamines

524

allosamidine inhibition test

861

alternan

606

applications

608

manufacture

606

properties

607

regulatory status

609

structure

607

structure of a portion

608

alternansucrase

606

alternase

607

Amadori rearrangement

607

44

American Association of Cereal Cemists

52

Amorphophallus aldus

892

Amorphophallus konjac

892

Amorphophallus rivieri

892

amphotericin B

524

amyloglucosidase

636

amylopectin

594

Anogeissus dhofarica

479


Index Terms

Links

Anogeissus latifolia

477

Anogeissus leiocarpus

479

Anogeissus pendula

479

Anogelline

479

anthrone-sulfuric reaction

602

AOAC method

281

Aquasorb cmc type A-500

721

Arabidopsis AtCesA gene

621

arabifuranohydrolase

669

arabinofuranosidases

660

arabinoxylans

xxiv

analysis and detection

479

68

621

669

apparent viscosity effect of shear rate

673

effect of shear rate and polymer concentration applications

674 679

cryostabilisers

680

film formation

680

surface active agents

680

content in various fractions of barley

663

effect of concentration on volume of baked bread

678

elastic modulus development during gelation

676

and ethanol co-production from wheat

662

extraction, isolation and purification

658

aqueous extraction from endospermic tissue

658

physical grain fractionation

662


653

Index Terms

Links

arabinoxylans (Cont.) strategies of extraction from agricultural by-products

660

xylooligosaccharides production

664

molecular and physico-chemical characteristics molecular structure

675 664

arabino(glucurono)xylans general structure

666

general molecular features

664

phenoxy radicals of ferulic acid

667

structural elements present

665

structural heterogeneity

667

neutral arabinoxylans general structure

654

neutral monosaccharides and phenolic acids

657

occurrence and content

655

physico-chemical properties

671

gelation

675

molecular weight

671

molecular weight variation of arabinoxylan preparation solution properties physiological effects

671 672 681

procedure for large-scale isolation and purification

659

role in bread-making

677

total and water soluble, in whole grains and grain tissues arachin

656 391


Index Terms

Links

Arako

891

arrum

410

Artemia urmiana

853

Asakura-Oosawa depletion potential

892

38

Ascophyllum nodosum

814

asialoglycoprotein receptors

525

Aspergillus aculeatus

664

Aspergillus niger

660

ASTM D-897

792

ASTM D-1002

792

ASTM D-2094

792

ASTM D-3528

792

ASTM E96-93

778

Astragalus gossypinus

496

Astragalus gummifer

496

Astragalus membranaceus

521

Astragalus microcephalus

496

Astragalus mongholicus

521

astragalus root

521

Astralagus gossypinus

502

Astralagus gummifer

502

atomic force microscopy

368

584

Aureobasidium pullulans

593

699

autohydrolysis

172

avenin

392

Avicel AC-4125

743

Avicel BV-1518

743

Avicel BV-2815

743

Avicel BV 2815

747

Avicel CL-611

742

775

746


Index Terms

Links

Avicel CM 2159

746

Avicel LM-310

755

Avicel PH

754

Avicel RC-501

742

Avicel RC-581

742

Avicel RC-591

742

Avicel RT 1133

742

Avicel-plus SD 4422

749

Avicel-plus stabiliser

749

avidin

364

axlewood

479

Ayurveda

487

Azotobacter vinelandii

808

Aztec marigold

523

749

746

B bacterial cellulose biosynthesis

724 726

mechanism

727

pathway

726

functional properties

730

crystallinity and degree of polymerisation

730

macromolecular structure

730

mechanical strength

731

miscellaneous properties

732

water-holding capacity

732

generalised model of ribbon assembly in A. xylinum historical overview

727 725


Index Terms

Links

bacterial cellulose (Cont.) manufacture

728

agitated culture

728

stationary culture

728

mechanical properties

732

regulatory status

736

structure

729

uses and applications

733

applications in paper and paper products

734

audio components development

734

biomedical applications

734

food applications

733

other applications

735

bacteriocin

764

Bakli

479

Bancroft’s rule

401

bassorin

502

benzoic acid

772

Bernoullian statistics

810

Beta Trim

628

betamethasone disodium

873

β-glucan synthase

621

β-glucanase

535

β-glucopyranose

711

1,3-β-glucosidic linkages

567

Bifidobacterium lactis

453

bioelectrodes

792

Biofills

735

biological response modifier

586

773

561

636

774


660

Index Terms

Links

Bioprocess

735

BioZate

338

bipolar membrane electroacidification

313

Blanose cmc type 7HOF

719

Blanose cmc type 7H3SXF

718

Blanose cmc type 7HXF

718

Blanose cmc type 7HXFMA

720

Blanose cmc type 9M31F

720

Blanose cmc type 9M31XF

718

bloom strength

147

β-mercaptoethanol

308

Botox

632

bovine serum albumin

366

Brewer’s grain

660

720

430

818

571

572

C Caco-2 cells

871

cadoxen

570

caffeine

522

calcitonin

870

Calpis

338

Calvin–Benson–Bassham cycle

394

capsaicin microcapsules

459

carboxymethyl cellulose

700

applications

717

bakery products

720

frozen products

718

general

717

instant products

718

low pH milk products

721


Index Terms

Links

carboxymethyl cellulose (Cont.) soft drinks

720

table sauces and dressings

719

idealised unit structure

717

properties

713

general

713

interaction with proteins

714

viscosity effect CMC-casein complex carob bean gum

715 237

carrageenan food applications

177

applications in dairy products

183

applications in water

181

dairy applications

181

water gels

178

furcelleran and other seaweed-derived products manufacture

164 165

manufacturing process

165

raw materials

165

physical properties acid stability

170 171

cation concentration effect on gelling temperatures gel properties

174 173

gel properties of pure and blended carrageenans

175

kappa carrageenan-kappa casein milk protein interaction pH stability

176 172


Index Terms

Links

carrageenan (Cont.) properties of solution

171

summary of properties

177

synergism with other gums

175

synergy with locust bean gum and konjac glucomannan thixotropic rheology regulatory status E407 structure

176 173 167 167 169

alkali modification

170

repeating units

171

caseinomacropeptide

328

caseinophosphopeptide

328

caseins

299

338

301

-based protein products industrial reparation and caseinates

304 303

and casein-derived milk protein products composition

306

fractionation

307

physico-chemical characteristics

299

302

Casocidin-I

329

339

casokinins

327

339

casomorphins

326

339

casopiastrin

328

casoplatelins

328

casoxins

326

Cellulase

636

Cellulon

735

339


Index Terms

Links

‘cellulose gel’ network

748

cellulosics

710

applications

714


717

hydroxypropyl cellulose

716

methyl cellulose and hydroxypropyl methyl cellulose methyl ethyl cellulose cellulose structure

714 717 712

formulations bake-stable filling

716

buttermilk drink pH4.5–4.6

721

fruit cake mix

721

ice cream

719

instant chocolate drink

718

instant fruit drink powder

718

ketchup

720

milk orange juice beverage pH4.5–4.6

722

potato croquettes

715

soya burgers

716

topping for whipping

717

water ice or ripple

719

idealised unit structure of cellulose gum

712

manufacture manufacturing process

711

raw material

711


Index Terms

Links

cellulosics (Cont.) properties

712


713

general

712

hydroxypropyl cellulose

713

methyl cellulose and hydroxypropyl methyl cellulose

713

methylethyl cellulose

713

regulatory status

722

ingredient declarations

723

names and serial numbers

722

permitted use levels

723

structure

711

cereal arabinoxylans

654

cereal β-glucans

615

biosynthesis

621

botanical distribution

617

chromatogram from lichenase hydrolysis

618

commercial products

628

extraction and purification

622

food applications

632

future trends

638

general structure

617

health benefits

624

alleviate blood pressure

627

alleviate diabetes

626

antimicrobial action

627

cancer prevention

627

626


Index Terms

Links

cereal β-glucans (Cont.) changes in serum total and LDLcholesterol

625

cholesterol-lowering effect

624

delay gastric emptying

627

626

interactions that may form junction zones between molecules

637

molecular weight and apparent viscosity

620

Nutrim-OB micrograph

629

processing

635

regulatory status

637

structure and analysis

617

variation in molecular weight

619

variation in sequence of triosyl units

618

wheat vs barley baked breads

633

cereals

386

chemical composition

388

composition of various grains

388

nutritional and health effects

414

protein composition and structure

394

Cerogen

626

CesA gene

621

chaconine

414

chaotropic agents

631

637

96

chaotropic salts

673

chemical peeling process

238

Chinese Kombuchar

733


Index Terms

Links

chitin and chitosan hydrogels

849

applications in drug delivery

869

drug delivery to intestine

875

pulmonary drug delivery

873

spray-drying

872

trans-dermal drug delivery

871

chitin as food component

860

chitosan chemistry

851

chemical structure and molecular characterisation

851

chitosan production

853

depolymerisation of chitosan

852

consumption of insects as food

860

food industry applications

867


861

cholesterol lowering in humans

863

overweight control

866

properties of chitosans and derivatives

853

gelation

855

polyelectrolyte complex formation

859

solubility

853

total digestion time of freeze-dried chitosan salts

866

chitinases

852

chitobiose

851

Chitopearl

864

chitosanase

852

chitotriosidase

861

chlorhexidine diacetate

873

chloropropanols

417


Index Terms

Links

chlorosulphonic acid

637

Choice dm

336

chondroitin sulfate

870

Chondrus crispus

165

chúcata

499

chymosin

320

Clarifoil

770

Clarisol

770

claudin

871

clearogel, see Scleroglucan clinical nutrition

69

enteral feeds

70

supplements

69

CMC, see carboxymethyl cellulose Coacervates, see protein-polysaccharide complexes coalescence

34

Codex Alimentarius Commission

5

Cohn process

395

colonic health

69

256

415

459

461

Committee on Food Additives and Contaminants

5

complex coacervation

422

confocal scanning laser microscopy

444

continuous centrifugal separators

399

conversions

119

acid hydrolysis

119

dextrinisation

119

enzyme hydrolysis

120

oxidation

119


Index Terms

Links

convicilin

393

Corynebacterium laevaniformans

603

cosmetics

161

co-solubility

421

creaming

31

Cross equation

37

cross-linking

115

cryo-TEM

443

Cryptococcus albidus

664

C-trim

628

629

C-trim20

629

632

C-trim30

629

632

C-trim50

629

Cucumis L. cv. ‘Laura,’

562

cupin

415

curdlan

567

applications

637

585

food applications

585

other applications

586

13

580

chemical structure

568

degree of thermo-irreversible gelation

583

C NMR spectra of curdlan gels

118

569

DSC heating curves 5% aqueous dispersions after heating

583

aqueous dispersions at various concentrations electron micrograph of curdlan granule

582 570

frequency dependence of storage and loss modulus

573


Index Terms

Links

curdlan (Cont.) functional properties aqueous suspension properties

570 573

solution properties and conformations thermal and morphological analysis gel network

570 582 579

gel strength concentration dependence

575

effect of urea

576

heating temperature effect

576

and syneresis at 30°C

577

and syneresis at 32°C

577

gelation

574

gel formation

574

gel properties

575

molecular conformations

577

580

high temperature structure at high humidity

581

at low humidity

581

hydrogen bond types in curdlan triple helix

579

light scattering and viscosity data

571

manufacture process

569

molecular weight dependence of meansquare radius of gyration

572

NaOH concentration dependence of intrinsic viscosity

572

native curdlan

568

neutralised curdlan gels morphologies

584


Index Terms

Links

curdlan (Cont.) production

568

regulatory status

588

room temperature structure

581

X-ray fibre diffraction pattern of anhydrous form

578

cyanoethylated pullulan

596

cystein-sulfuric acid reaction

602

D Dahlquist criterion

787

Dahurian larch, see Larix dadurica dairy products

181

dalarelin

458

D-arabitol

728

Davedi

479

Dawn multi-angle laser light scattering method

895

deacetylation

853

de-arabinosylation

669

debranning

661

dehydrodiferulic acid

668

denaturation temperature

153

dental moulds

103

desolventizer-toaster

399

detarium

539

540

dextran

609

671

applications

611

chemical structure

610

manufacture

609

663

541


542

Index Terms

Links

dextran (Cont.) properties

611

regulatory status

612

structure

610

dextransucrase

610

D-glucono-δ-lactone

822

Dhanta

479

Dhao

479

Dhawra

479

Dho

479

diclofenac-sodium

522

dietary fibre

52

effects on metabolism and health colonic health

55

57

68

69

gastrointestinal tract and impact on other nutrients

57

metabolic syndrome : obesity appetite and anti-inflammatory effects

61

diethylaminoethyl dextran

870

diethylmethyl chitosan

871

differential scanning calorimetry

679

diffusion theory of adhesion

784

diguanylate cyclase

727

dimethylformamide

594

dimethylsulfoxide

570

Dindal

479

Dindiga

479

dithiothreitol

308

68

594

598


611

Index Terms

Links

E E407

167

E407A

167

Eastern larch, see Larix laricina edible fibre

99

insoluble fibres

99

soluble dietetic fibres

99

egg proteins

359

egg white foams

369

egg yolk emulsions

365

gels

373 basic principles

373

egg white

375

egg yolk

374

II/A isotherms of different lipid constituents

368

LDL adsorption mechanism at oilwater interface

369

mean droplet diameter and creaming index

367

parameters of kinetic of diffusion towards air-solution interface physico-chemistry and structure

371 360

egg white

363

egg yolk

360

technofunctional uses egg white foams egg white foams

359 363 369 370

372


Index Terms

Links

egg white (Cont.) formation and stabilisation mechanisms

369

interfacial properties of proteins

370

key parameters

372

gels

375

glucidic and mineral functions

365

hen egg white composition proteins

364 364

avidin

364

composition and physico-chemical and functional properties

365

interfacial characteristics

372

lysozyme

365

ovalbumin

364

ovomucin

365

ovomucoïde

364

ovotransferrin

364

egg yolk

360


360

emulsions

365

basic principles

365

importance of assemblies

366

role of constituents

366

gels

368

374

hen egg yolk composition

361

fractionation of plasma and granules

361


Index Terms

Links

egg yolk (Cont.) physical state of granules as function of pH and ionic strength repartition of constituents macrostructure and main constituents

363 362 360

‘egg-box’ model

813

electrical model theory

784

electron beam irradiation

680

electron microscopy

392

electrostatic interactions elsinan

27 600

applications

602

manufacture

600

properties

601

regulatory status

603

segment structure

601

structure

601

Elsinoe leucospila

600

Emivirine

521

emulsifier E473

774

emulsifiers

xxiv

emulsifying agent

774

24

emulsion stability and hydrocolloids

23

adsorbing hydrocolloids effect

42

non-adsorbing hydrocolloids effect

35

oil-in-water emulsion instability mechanism principles

25 26


Index Terms

Links

emulsion stability (Cont.) theoretical reaction potential of spherical emulsion droplets

27

endoglucanases

607

endoxylanases

660

Ensure

336

enteral feeds

70

enzymes

194

epichlorohydrin

605

epigallocatechin gallate

548

551

Escherichia coli

857

868

EU food legislation

415

Eucheuma denticulatum

165

Eudragit S100

876

European larch, see Larix deciduas Evolus

338

exoglucanases

607

exudate gums

xxiv

F fats

124 and oils

127

ferulic acid esterase

660

feruloylation

668

flash desolventizer system

399

flocculation depletion and serum separation

31 38

Flory plot

540

Flory universal viscosity constant

571

fluorescein isothiocyanate chitin

861


Index Terms

Links

FMC BioPolymer

809

food hydrocolloids

1

commercially important hydrocolloids

2

food products containing hydrocolloids

3

hydrocolloid fibres

19

fermentation product effect

20

future trends

21

health benefits

20

physical effect

19

regulatory aspects

5

European system

6

international

5

International Numbering System for Food Additives other trade blocks synergistic combinations

8 7 18

interactions in hydrocolloid mixtures

18

thickening characteristics

8

disaccharide repeat units

13

main hydrocolloid thickeners

14

viscosity–shear rate profile

11

10

viscosity–shear rate profile for 1% guar gum

12

viscosity–shear rate profile for 1% xanthan gum 1% CMC 1% guar gum 20% dextran and 30% gum arabic

12

zero shear viscosity log as a function of polymer concentration

10


Index Terms

Links

food hydrocolloids (Cont.) viscoelasticity and gelation

14

18

frequency dependence for 1% xanthan gum solution and 1.5% amylose gel

15

frequency dependence for guar gum solutions at concentrations of 0.5% and 2.0%

14

gel texture comparison

16

main hydrocolloid gelling agents

17

world market for hydrocolloids formamide

5 611

637

formulations 30% oil dressing with roasted sesame seeds and Dijon mustard

200

bake-stable fruit preparation

225

chilled liquid cake mix

199

cooked ham with 30% added brine

179

dairy ice cream mix

182

dessert jelly

215

flan dessert

181

fluid gel for beverages

217

fruit juice jelly

214

fruit-flavored water dessert jelly

178

jelly sweets

222

jelly sweets using gellan gum and thin boiling starch

222

peach yogfruit

224

pulp suspension beverages

218


Index Terms

Links

formulations (Cont.) reduced sugar jam

224

vinaigrette-style salad dressing

180

Fourier transform infrared spectroscopy

440

Fox-Flory theory

544

freeze-fracture microscopy

442

freezing-thawing method

87

French wheat flours

668

fructan

604

fructo oligosaccharides

838

fructofuranosyl rings

604

Fry Shield

767

FT-Raman spectroscopy

670

full press method

398

Furcellaria

165

670

853

374

furcelleran carrageenan and other seaweed-derived products

164

G galactomannans

195

228

annual consumption of certain hydrocolloids

230

future trends

250

manufacture

237

carob bean gum

237

fenugreek gum

242

guar gum

239

guar splits and gum powder

240


895

Index Terms

Links

galactomannans (Cont.) raw materials and structure

229

aleurone cell layers

232

Dreiding model of galactomannan

234

233

235

GPC chromatogram of xanthan, guar and carob bean gum

236

guar seed cross section

233

model in carob bean gum

233

theoretical repeating units of galactomannan

234

regulatory status

249

technical data

243

carob bean gum analysis

249

245

cold swelling carob bean gum power law data

248

fenugreek seek analysis

246

guar solutions acid stability

248

gum content in fenugreek

246

other guar products power law data

248

polynomial equation coefficients

247


249

carob bean gum functional properties

250

gastric emptying

57

gastrointestinal tract

57

colonic effects

58

prebiotic effects and interactions

60

production and effects of short chain fatty acids

59

second meal effects

58


236

Index Terms

Links

gastrointestinal tract (Cont.) small intestine effects

57

upper gut effects – gastric emptying

57

Gas-X Thin Strips

770

gatifloxacin

875

GATIFOLIA

480

GATIFOLIA SD

488

Gaviscon

822

gel permeation chromatography

260

314

485

895 gelatin

142

applications

158

bloom values, concentration and function in some food

159

confectionery

159

cosmetics

161

foods

159

nutritional and health proprieties

161

pharmaceutical and medical

160

photography

162

chemical composition and physical properties

149

10% bovine, warm and cold water fish gelatin gelling kinetics amino acids

155 150

bloom maturing process for 6.67% mammalian gelatin

156

collagen and gelatin chemical composition

149


851

Index Terms

Links

gelatin (Cont.) collagen and gelatin physical properties

152

helix amount in 2% cold water fish gelatin solution

154

molecular weight distribution

151

thermoreversible gelling process

154

types A and B gelatins with similar Bloom values gelatin derivatives

152 157

chemically modified gelatin

158

cold water soluble

157

hydrolysates

157

manufacturing

143

acid pre-treatment

145

alkaline pre-treatment

145

from extraction to final product

145

gelatin manufacturers

146

polypeptide chains with varying molecular weight

146

raw material consumption for the gelatin production raw material sources

144 143

regulations, technical data and standard quality test methods

147

bloom strength

147

quality control

149

viscosity

148

gelatinisation Gelidiella

112 84


Index Terms

Links

Gelidium amansii

84

gellan gum

4

future trends

225

manufacture

205

regulatory status

225

structure

205

primary structure technical data

204

205 206

calcium, sodium and potassium effects

210

common sequestrants

208

dispersion

206

effect of dissolved salts on hydration temperature

207

gel texture comparison

212

gelation

208

211

gum blend ratio effect on modulus and brittleness

213

gum gel properties for gel formation in 60% sucrose

210

gum gel properties for gel formation in water

210

hydration

206

sodium citrate effect

207

texture

211

texture profile high and low acyl gum gels uses and applications

212 213

dairy

218

dessert jellies

214


Index Terms

Links

gellan gum (Cont.) effect of sugar on textural properties

221

formulation guidelines

217

fruit preparations

221

223

high and low acyl gum gel properties

214

other applications

224

potential processes for fluid gels

216

pre-gelation prevention

223

raw fruits ionic composition

223

sucrose concentration effect on modulus, hardness and brittleness

220

sugar confectionery

219

suspending agent

215

gelling memory

94

Gengiflexs

735

genipin

857

Gigartina

165

gliadin

392

394

globulins

391

394

Glucagel

631

632

glucansucrases

606

Glucerna

332

glucomannan

894

glucomannan fibre

637

336

68

glucomannans

195

Gluconoacetobacter xylinum

725

glucopyranosyl monomers

617

glucose oxidase-peroxidase reagent

620

glucurono(arabino)xylans

665

728


Index Terms

Links

glutamate glucan

858

glutaraldehyde

858

glutelins

392

gluten

394

glycerolmonostearate

768

Glycine max

694

glycinin

389

glycomacropeptide

314

Glyloid

537

glyoxal

858

glyoxylic acid

869

Gouda cheese

455

Gracilaria green leaves and fruits

393

84 387


389

food application

412


414

processing

399


394

Grinsted Xanthan 200

189

Grinsted Xanthan CLEAR 200

189

Grinsted Xanthan EASY

189

Grinsted Xanthan SUPRA

189

Grinsted Xanthan ULTRA

189

guanosine triphosphate

726

guar gum

239

derivatives

242

guar pods and seeds

240

seed components

241

Guinier plots

391

594

542


Index Terms gum arabic

Links 43

252

488

703 applications

270

beverages

271

confectionery

270

dietary fibre

271

flavour encapsulation

271

arabinogalactan component

263

arabinogalactan protein complex structure caramel-type products formulation

264 270

definition Codex Alimentarius Advisory Specification for Gum arabic

258

EU Gum Arabic Specification

258

European Pharmacopoeia

258

FAO Food and Nitrition Paper No. 49 1990

256

51st meeting of Joint Expert Committee on Food Additives

257

49th meeting of Joint Expert Committee on Food Additives United States Food Chemical Codex

256 259

United States Pharmacopeia and the national Formulary

259

effect of shearing time on viscosity of gum arabic solutions

267

EU Gum Arabic Specification

258

European Pharmacopoeia

258

new comprehensive regulatory status

259


702

Index Terms

Links

gum arabic (Cont.) United States Food Chemical Codex

258

United States Pharmacopoeia and the national Formulary flavour encapsulation formulation

259 271

gel permeation chromatography Elution profiles

268

UV absorbance elution profiles

269

grades of Sudanese gum

254

manufacture

255

marshmallow formulation

270

properties

265

regulatory aspects

256

stabilisation of oil droplets

268

storage and loss moduli

267

structure

260

supply and market trends

254

twisted hairy rope proposal AGP

505

viscosity as function of concentration

265

vs xanthan gum vs sodium CMC viscosity shear rate gum ghatti

266 477

formulations

488

butter cream

490

dressings

490

mayonnaise type dressing

489

MCT

488

orange oil, ester gum, β-carotene MCT orange oil–ester gum

489 489


Index Terms

Links

gum ghatti (Cont.) gum ghatti nodules

478

manufacture

480

regulatory status

491

Asia

491

Australia

493

Japan

492

Russia

493

South Africa

493

South America

491

United States

492

structure

480

technical data

483

emulsification

486

molecular weight

484

physico-chemical parameters

483

rheology

486

solubility

483


487

beverage emulsion

488

butter cream

490

dressings

490

mayonnaise type dressing

489

viscosity as function of concentration

487

vs gum arabic amino acid composition

484

elution profile after fractionation

485

emulsification performance and stability

488


Index Terms

Links

gum ghatti (Cont.) physico-chemical and molecular weight parameters gum karaya

483 488

manufacture

498

product specification

510

regulatory status

526

structure

503

technical data

510

adhesive properties

513

compatibility

513

film-forming properties

513

heat stability

513

pH stability

512

preservative

513

rheological properties

512

solubility

511

viscosity

511

water-binding properties

513


521

food applications

521

industry

522

pharmaceutical uses

522

gum tragacanth grades in Turkey Bianca

497

Fior

497

Fior Extra

497

Pianto

497

major components

502


Index Terms

Links

gum tragacanth (Cont.) manufacture

496

pectic component structure

502


508

regulatory status

525

structure

501

technical data

508

acid stability

509

compatibility

510

emulsification ability

510

heat stability

510

preservatives

510

rheological properties

509

solubility

508

surface activity

509

viscosity

508


519

food applications

519

non-food applications

520

pharmaceutical applications

520

Gummi indici

479

Gummi indicum

479

gummosis

496

Gymnema sylvestre

867

H hashab

253

heat-induced gelation

374

helianthinin

391

helices

111


Index Terms

Links

hemicellulose

725

heparin

458

Hercules

767

high acyl gellan gum gelation

211

hydration

208

high methoxyl pectin

700

Hobart

752

homogalacturonan

695

homopolysaccharide

593

hordein

392

Huang Ch’i

521

Humicola insolens

661

hydrocolloid emulsifying agents hydrocolloids

664

42 1

90° peel test curves

791

coated garlic

766

for coatings and adhesives

760

adhesion mechanisms

783

adhesion tests

788

adhesive hydrocolloid preparations

782

film-application techniques and stages

777

food uses and applications of adhesives future trends

784 792

inclusion of food additives in edible films

771

market estimates for edible films

779

methods for testing coatings

778


Index Terms

Links

hydrocolloids (Cont.) next generation of edible films and possible research direction non-food coatings

779 776

non-food uses and application of adhesives

781

novel products

769

parameters to be considered in food coating

775

structure-function and hydrogeladherend relationships

786

uses and applications of bioadhesives

785

edible protective films

761

coatings for fried products as oil resisters edible packaging materials

766 761

gum coatings for fruits and vegetables

764

meat, seafood and fish coatings

762

miscellaneous coatings

767

emulsifying/stabilising agents and emulsion stability

834 23

gellan-sitosterol-coated garlic

766

gelling agents

834

health aspects

50

clinical nutrition

69

effects on metabolism and health

55

future trends

70

mechanism of action

56

57

68


Index Terms

Links

hydrocolloids (Cont.) non-digestible carbohydrates in food

51

modified probe-back test

789

Oblate

767

thickening agents

834

toffee coated by edible film

767

as wet glues

790

hydrogels

783

hydrolysed oat flour

622

792

hydrolysed starch-polyacrylonitrile copolymers hydrophobic hydration

776 787

hydrophobically modified cellulosic thickeners

776

hydroxypropyl cellulose applications

716

properties

713

hydroxypropyl methyl cellulose applications

714

properties

713

hydroxypropyl-β-cyclodextrin

873

hyperentanglements

545

hysteresis

173

I immunoglobulins

314

immunoglobulins Y

452

incipient gel temperature

713

Indian gum

479

insulin

870


Index Terms

Links

intelligent gels

855

International Numbering System for Food Additives

8

hydrocolloids

9

modified starches

8

Inula helenium

829

inulin

829

absorption profiles

843

applications

839

fat spreads and dairy spreads

840

fillings

842

low-fat and low-sugar ice cream

841

low-fat cake

842

low-fat hazelnut spread

843

low-fat mayonnaise/dressing

841

low-fat yoghurt

841

wafers

842

basic chemical structure

830

effect of shear treatment and seeding on firmness

837

effect on creaminess of skimmed yoghurt

841

effect on rheology of carrageenan gel

834

effect on starch viscosity

835

future trends

844

gel strength in relation to concentration

837

hydrolysis of different types at pH 3.5

833

inulin content of different crops

830


Index Terms

Links

inulin (Cont.) long-term solubility at different temperatures

832

maximum solubility as function of temperature

832

nutritional and health benefits

838

overview of applications

840

overview of nutrition claims from EU 1924/2006

844

procedure for making inulin gel

836

production process

831

regulatory status

843

seeding process

837

technical properties

831

acid stability

833

heat stability

833

inulin and hydrocolloids

833

inulin as gelling agent

835

parameters affecting gel characteristics

836

solubility

831

viscosity

832

ion exchange chromatography

314

ionotropic gelation technique

859

Iranian grading system

497

Isogel

51

isomaltodextranases

607

isothermal titration calorimetry

864

isracidin

329


Index Terms

Links

J Japanese larch, see Larix leptolepsis jelly mini-cups

824

Joint Expert Committee on Food Additives

5

256

296

594

595

723

744

824

K kallikrein-kinin system

327

kami

781

Kanten

86

Kappacin

329

Kappaphycus alverezii

165

Kardhai

479

KELCOGEL

205

KELCOGEL F

205

KELCOGEL LT

205

KELCOGEL LT100

205

Kenwood

752

Kerry Ingredients

767

ketoprofen

459

kibbling

255

Kitchenaid

752

Klebsiella pneumonaie

327

339

konjac flour analytical results of components

894

manufacture production process

892

purification

893


Index Terms

Links

konjac flour (Cont.) purified analytical results of components

897

scanning electron micrograph

894

Rheolex RS, relationship between viscosity and stirring time scanning electron micrograph konjac mannan

897 893 889

applications and functional uses

900

chemical structure

896

effect of pH on viscosity change

898

FT-IR spectrum analysed by attenuated total reflection method

895

and κ-carrageenan with various compositions effect of salt concentration

899

effect of sugar concentration

899

konjac plants

890

manufacture

892

cultivation

892

production process

892

purification

893

and other gums with various composition gel strength

898

viscosity

898

purified, scanning electron micrograph

894

regulatory status

900

structure

894

technical data

896


Index Terms

Links

konjac mannan (Cont.) two-year-old tubers

891


899

Kon-nyaku

891

Kuhn length

541

kuzu mochi

555

899

L lactalbumin

312

337

Lactobacillus acidophilus

453

Lactobacillus brevis

681

Lactococcus lactis

325

lactoferricin

329

336

339

lactoferrin

314

325

337

lactoferroxins

326

lactokinins

327

lactoperoxidase

314

lactorphins

326

lactotransferrin

337

Laminaria hyperborea

808

Langevin dynamics

424

Langmuir Blodgett transfer

368

Langmuir film balance

368

Langmuir monolayers

516

lap-shear test

788

325

larchwood arabinogalactan manufacture

500


518

regulatory status

527

structural features

507


Index Terms

Links

larchwood arabinogalactan (Cont.) structure

505

technical data

517

moisture retention and shelf-life

519

mouthfeel

519

osmolality

518

solubility

518

stability to pH

518

viscosity

518


524

biomedicine

524

food

525

industry

524

508

Larix dadurica

501

Larix deciduas

501

524

Larix laricina

501

524

Larix leptolepsis

501

Larix occidentalis

500

501

Larix siberica

501

524

leaf protein concentrate

387

legumes

384


388

chemical composition of soybean defatted meal, concentrate and isolate

396

forage legumes

384

green legumes

384

farmed

food applications of main soybean protein preparations

409


Index Terms

Links

legumes (Cont.) nutritional and health effects

413

popular grain legumes

385

protein composition and structure pea

393

soybean

393

protein structure or soybean 11S globulin

390

soymilk, soywhey, tofu and okara production

411

legumin

393

legumin-like globulins

391

Leuconostoc mesenteroides

606

levan

603

applications

605

chemical structure

604

manufacture

603

properties

604

structure

604

Lifshitz-Slezov-Wagner theory

609

35

lignin

725

lipophilic substitution

120

Listeria innocua

772

Listeria monocytogenes

764

Listerine PocketPaks

769

locust bean gum

175

locust bean gum-xanthan system

786

773

868

low acyl gellan gum gelation

209

hydration

206

211


Index Terms

Links

low-methoxyl pectin

767

low-viscosity tamarind seed gum

556

LVSTX, see low-viscosity tamarind seed gum lysozyme

365

372

375

439

540

672

851

M Maltese Cross

112

maltodextrin

594

maltooligosaccharides

622

maltotetraose

593

maltotriose

593

Manchurian Tea

733

Manners’ method

568

Mark–Houwink equation

505

MCT, see edium chain triglyceride medium chain triglyceride

487

Mentha spicata

868

mercaptodextran

611

mesquite gum analytical parameters for Prosopis velutina and specifications for Prosopis laevigata

514

carbohydrate component structure

504

definition

499

manufacture

499

regulatory status

526

structure

503

505


Index Terms

Links

mesquite gum (Cont.) technical data

513

compatibility

517

effect of pH

515

emulsification ability

516

encapsulation ability

516

film forming

517

preservatives

517

solubility

514

surface activity

515

viscosity

514

uses and applications flavour and colour emulsification

522 523

flavour and colour microencapsulation non-food applications metabolic syndrome

523 523 61

appetite regulation

62

blood glucose and insulin sensitivity

64

blood lipids

66

RCT on hydrocolloid effects

68

68

67

body weight reduction and weight management modulation of satiety-related hormones

61 64

subjective feelings of appetite and satiety systemic anti-inflammatory effects Metamucil

63 69 51


Index Terms

Links

methyl cellulose

717

applications

714

properties

713

methylation

670

methylation analysis

617

methylethyl cellulose properties

713

methylpyrrolidinone chitosan

874 ′

4-methylumbelliferyl-β-D-N,N diacetylchitobiose

861

metoclopramide HCl

874

Michael addition reaction

855

microbial polysaccharides

xxiv

microcrystalline cellulose

740

Avicel characteristics

752

food applications and functionality

745

592

beverages (high temperature stability)

746

beverages (low pH stability)

747

beverages (suspension of solids)

745

bulking agent, fat replacer, flow aid tablet exipient

754

dressings, sauces and cooking cream

748

ice cream

752

vegetable fat whipping cream

749

whipping process

752

formulations acidified milk-juice beverage

749

an indulgent healthy chocolate everage

746


Index Terms

Links

microcrystalline cellulose (Cont.) calcium fortified, recombined soy beverage

747

low fat ice cream

755

nougat style confections

756

retorted adult nutritional beverage

748

UHT dairy cooking cream

750

vegetable fat whipping cream

751

future developments MCC-based bulking agent for fat and sugar calorie reduction

757

MCC/food approved hydrocolloids

757

MCC/lipids

757

low fat ice cream air cell integrity

753

air cell structure

754

molecular structure of cellulose

741

nutritional and regulatory information

743

physical properties

744

raw materials and manufacturing process

741

strain sweep curve

745

thixotropy

745

viscosities obtained at different fat levels

750

microencapsulation

271

Microquick WC-595

743

milk proteins

298

application baked products

330


Index Terms

Links

milk proteins (Cont.) beverages

333

confectionery products

335

convenience foods

340

dairy-type products

331

desert-type products

334

meat products

336

nutritional/medical/pharmaceutical applications

337

pasta products

334

textured products

341

biological activity

324

intact caseins

324

intact whey proteins

325

biologically active peptides

326

ace inhibitory peptides

327

antibacterial peptides

329

antithrombotic peptides

328

caseinophosphopeptide

328

immunomodulatory peptides

327

opioid peptides

326

composition of bovine milk

299

distribution of proteins in bovine milk

300

food uses

329

bakery products

329

beverages

332

confectionery

335

convenience foods

339

dairy products

331

dessert-type products

333


Index Terms

Links

milk proteins (Cont.) films and coatings

341

meat products

336

nutritional/medical/phamaceutical applications

336

pasta products

334

textured products

340

functional properties

317

emulsifying and foaming properties

323

gelation and coagulation

319

hydration properties

320

solubility

317

surface active properties

322

viscosity

321

future trends

341

milk protein system

299

the milk protein system caseins

299

whey proteins

301

production of milk protein products

301

303

caseins and caseinates

303

casein-whey protein co-precipitates

315

fractionation of caseins

307

fractionation of whey proteins

312

milk protein concentrates/isolates

315

milk protein hydrolysates and biologically active peptide fractions

316

modified milk protein products

316

whey protein-enriched products

308

311


Index Terms Miscellaneous Additives Directive

Links 6

modified probe-tack test

789

molecularly imprinted polymers

855

3-monochloropropane-1,2-diol

418

MonoQ anion exchanger

314

Monte Carlo simulation

434

Morgan-Elson reaction

602

morphine

870

moxifloxacin

874

multi-angle laser scattering

485

439

N N, O-carboxymethyl chitosan

765

N-acetylcysteine

771

N-acetylglucosamine

852

nanolaminates

780

nanotechnology

779

‘nano-whiskers’

779

1-naphthol-4-sulphonic acid

856

1-naphthylamine-4-sulphonic acid

856

naproxen

458

Nata de Coco

733

Natureal

630

N-carboxymethyl chitosan

856

Nigerian No. 2

255

Nikan Sui method

772

94

nimodipine

522

nisin

764

772

NMR spectroscopy

670

851


Index Terms non-digestible carbohydrates in food

Links 51

definition and properties

51

other non-digestible carbohydrates

54

physico-chemical properties and physiological effects non-starch polysaccharides

54 53

nori

769

771

Novagel RCN

755

NovaMatrix

809

nuclear magnetic resonance

443

nuclear Overhauser effect

550

nutraceuticals

xxiv

Nutrim-5

633

Nutrim-OB

628

637

Nuture 1500

630

637

Oatrim

622

628

OatVantage

632

637

OatWell

637

OatWell 14% Oat Bran

630


630


630

Oblate

767

occludin

871

ofloxacin

870

oilseeds

386

O


389


414


Index Terms

Links

oilseeds (Cont.) sunflower oil and defatted meal manufacture

398

okara

693

orcinol-HCl

669

organic natural oat fibre

630

Origami Foods

770

oscillatory small-deformation rheology

512

Ostwald disproportionation

370

695

637

638

34

402

516

ovalbumin

364

370

375

ovomucin

365

375

ovomucin-lysozyme complex

364

ovomucoïde

364

375

ovotransferrin

364

375

oxidative- reductive polymerisation

815

6-oxychitins

854

oxygen transfer coefficient

729

oxygen transfer rate

729

Ostwald ripening

P pea, see legumes pectinase pectins

865 43

chemical nature

54

274

277

formulations bakers jam

287

baking stable fruit preparation

287

concentrated glaze

288

extra jam

284


439

Index Terms

Links

pectins (Cont.) fruit flavoured confectionery jelly with buffered pectin

295

fruit flavoured confectionery jelly with unbuffered pectin

295

fruit flavoured dessert jelly

294

fruit preparation for yoghurt

289

milk/fruit juice drink

292

orange marmalade

284

ready-to-use spray glaze

288

reduced sugar raspberry jam

285

reduced sugar strawberry jam

285

requirement for traditional jam at 65% soluble solids

283

set and stirred yoghurt

292

syrup for milk dessert

293

Turkish delight jelly

296

yoghurt drink

291

galacturonic acid, ester and amide units

275

gel strength variation of low methyl ester pectin gels

280

hypothetical structure of apple pectin

278

legal status

296

manufacture

275

production processes

276

raw materials

275

nutritional and health aspects

281


Index Terms

Links

pectins (Cont.) properties and function

277

availability of pectin types

280

gelation properties

279

range of commercial non-amidated pectins uses and applications

281 282

dairy products

290

dissolving pectin

282

fruit preparations and fruit bases

289

293

fruit preparations for bakery products

286

high sugar jams, jellies, marmalades and preserves

283

industrial fruit preparations

286

lower sugar jams and jellies

283

optimising pectin formulations

282

other dessert products

293

other food applications

296

sugar confectionery

294

286

variation of gel strength and setting temperature of high methyl ester pectins

279

pediocin

772

peel test

778

pentosans

654

perturbation theory

439

788

PES, see processed Euchema seaweed phlorizin

560

phloroglucinol-HCl

669


Index Terms

Links

phosphocaseinate

304

phthalic anhydride

776

phycocolloids

100

Phycomyces blakesleeanus

853

phytoalexin

561

Phytophthora megasperma

562

plant exudate gums

495

Plantago sp

665

Poisson–Boltzmann equation

433

polyacrylic acid

776

polydispersity index

812

polyethylene oxide

776

poly(4-hydroxystyrene)

857

polysaccharides porogen

772

44 857

potato, see root vegetables pregelatinisation

120

pre-press solvent extraction

398

pressure-sensitive adhesive

786

Prima Cel

735

processed Euchema seaweed

4

E407A

167


166

Prodiet F200

335

Progesterone

873

prolamin

392

Pro-long

766

propylene glycol alginate

700

Prosopis juliflora

499

Prosopis laevigata

499

399

167

415

809

814

514

526


Index Terms

Links

Prosopis velutina

499

protein dispersibility index

410

protein hydrocolloids protein-polysaccharide complexes

xxiii

503

514

xxiv

420

external parameters and analytical techniques used for investigation

426

external parameters influencing formation

425

binding enthalpy evolution

436

ionic strength

432

pH

430

pH-induced evolution

431

protein to polysaccharide weight ratio

434

temperature, shearing and pressure

435

total biopolymer concentration

435

food applications

452

food products texturisation

455

interface stabilisation

456

microencapsulation

453

other food application

457

protein purification

452

whey protein isolate/acacia gum complexes in ice-cream mix formation energetics

457 422 423

exothermic signals upon titration of β-lactoglobulin with acacia gum

424

theoretical models

423

thermodynamic background

422


Index Terms

Links

protein-polysaccharide complexes (Cont.) functional properties

445

adsorption at air/water interface and foaming properties

449

adsorption at oil/water interface and emulsifying properties

447

β-lactoglobulin/acacia gum complexes formation of thick interfacial layer solubility and rheological properties

451 445

internal parameters influencing formation

438

biopolymer charge density

438

biopolymer molecular weight

439

non-food applications

458

biomaterials

459

microencapsulation

458

structure, morphology and coarsening

440

aggregate-free β-lactoglobulin/acacia gum mixture

444

β-lactoglobulin and acacia gum aggregated complexes

442

coarsening mechanism and macroscopic level

443

mesoscopic level

441

microscopic level

443

molecular level

440

systems used for microencapsulation purposes in food and non-food applications

454


Index Terms protein-polysaccharide emulsifiers

Links 44

effect of interaction on proteinstabilised emulsion

45

protopectins

277

Pseudomonas sp.

603

pseudoplasticity

171

Pterocladia pullulan

84 450

applications

595

cyanoethylated

596

manufacture

593

properties

594

regulatory status

596

segment structure

594

structure

593

pullulan PI-20

593

451

593

594

Q qemai

781

quantum satis principle

824

Quarg

332

Questran

864

R radix astragali

521

Rapid Viscosity Analyser

112

rasping machine

399

Regulan

51

renneting

445

629


699

Index Terms

Links

resistant starch

123

Resource

332

retrogradation

113

revitalised wheat gluten

416

rhamnogalacturonan

695

rhamnogalacturonoglycan

503

rheology

36

constant viscosity at low pH

194

flow behaviour comparison

192

189

flow curve of 0.5% xanthan gum solution in standardised tap water pH sensitivity

191 193

solution stability to acids at ambient temperature

194

structure/property relationship for xanthan gum

190

Rhynchelytrum repens

628

Ricotta cheese

332

rituximab

627

root vegetables

386


389


414


394

rubisco

394

S Salmonella typhimurium

764

Schiff base

855

858

Schiff reaction

857

859

schizophyllan

598


Index Terms

Links

Schizophyllum commune

598

Scientific Committee for Food

744

scleroglucan

596

applications

599

manufacture

597

properties

598

regulatory status

600

repeating unit

598

structure

597

858

sclerogum, see Scleroglucan Sclerotium glucanicum

596

Sclerotium rolfsii

597

screw press method

398

secalin

392

597

Seiko, see konjac flour Semperfresh

766

Sephadex

612

Shimla

483

shiruko

553

Siberian larch, see Larix siberica single cell protein

399

size exclusion chromatography

671

slow release protein

338

small angle neutron scattering

263

442

small angle X-ray scattering

392

443

Smith degradation

503

Soafil

764

Soageena

768

573

sodium carboxymethyl cellulose, see carboxymethyl cellulose This page has been reformatted by Knovel to provide easier navigation.

Index Terms

Links

sodium cyanoborohydride

858

sodium-alginate coating

765

solanine

414

solubilised wheat gluten

416

soluble soybean polysaccharide

693

basic material properties and characteristics

696

adhesive strength and material property of film

699

antioxidative effect on soybean oil

699

antioxidative property

699

excellent adhesive and film-forming property high dietary fibre content

699 696

high solubility and stable viscosity against heat, acid and salts change in taste value of boiled rice

696 705

coating phase on surface of cooked noodles

706

foam stability test results

705

functional properties and applications

700

anti-sticking effect

704

emulsification test results

704

emulsifying stability

702

foam stabilising function

704

formulation of flavour emulsions

703

other applications

706

preparation of flavour emulsions

703

protein particles stabilisation

700

galacturonan region distribution

696


Index Terms

Links

soluble soybean polysaccharide (Cont.) and HM-pectin effects on dispersion of acidic milk protein

702

main fraction structure

697

manufacture

694


695

regulatory status

706

stabilising mechanism emulsion oil droplet

704

protein particles under acidic conditions structure

702 694

general composition

694

SSPS structure

695

viscosity change by heating at various pH ranges

698

comparison of various polysaccharide solution effect of various salts on

698 698

soy protein isolate

693

SOYAFIBE-S

693

functions and applications

700


694

varieties

701

SOYAFIBE-S-DA 100 chemical composition

694

694 695

SOYAFIBE-S-LA200

700

soybean fibre

706

soybean hemicellulose

706


Index Terms

Links

soybean polysaccharide

706

soymilk

693

Spiro

488

Spiro exudation

478

St. John’s bread

229

stabilisation

118

‘Stain Hall’ procedure

781

starch

108

manufacture extraction

109

sources

109

starch granule characteristics

110

modifications

115

118

chemical and biochemical modifications

118

conversions

119

cross-linking

115

lipophilic substitution

120

pregelatinisation

120

stabilisation

118

thermal treatment

121

type of starch modification

116

regulatory status modified starches as food additives

118

137 138

permitted food starches under European law

138

starches and modified starch product labelling

139

starches and modified starches as food ingredients

139


Index Terms

Links

starch (Cont.) structure

110

advantages/disadvantages vs other hydrocolloids

114

gelatinisation, gelation and retrogradation helix formation

112 111

native starches gelatinisation properties

114

starch granule

111

starch polysaccharides

110

technical data

121

effect of crosslinking and stabilisation

122

nutrition

122

structure-function relationship

121


125

baked goods

128

batters and breadings

129

beverage emulsions and flavour encapsulation

130

confectionery

130

dairy products

131

effects of food processing

127

fruit preparations

132

gravies, soups and sauces

133

mayonnaise and salad dressings

135

meat products

136

savoury snacks

136

sensory attributes

126


Index Terms

Links

starch (Cont.) starch selection

125

viscosity troubleshooting

137

starch polysaccharides

110

amylopectin

111

amylose

110

static light scattering microscopy

444

sterculia gum, see gum karaya Sterculia setigera

498

Sterculia striata

512

Sterculia urens

498

511

786

787

Sterculia villosa

498

steric interactions

29

Stokes’ Law

31

Streptococcus pyogenes

325

Streptococcus sp.

603

sucrose acetate isobutyrate

271

sucrose esters

774

sugar icings

101

sugars

126

supplements

501

sweet potato sweet

101

agar fabrication diagram synergies

512

521

279

319

69

Svedberg’s method

syneresis

511

87

167

88 94

acid and alkaline hydrolysis

96

agar-locust bean gum

95

gelling blockade by chaotropic agents

96


Index Terms

Links

synergies synergies gelling blockade by tannic acid

96

sugar reactivity

95

synergism

175

T Takeda Chemical Industries Co.

568

Tal Pro-long

766

Talaromyces emersonii

660

talha

253

tamarind kernel powder

537

tamarind seed

539

tamarind seed xyloglucan

535

gelation

541

551

and LVTSX concentration dependence of steady shear viscosity preparation

556 537

see also yloglucan Tamarindus indica tannic acid

535

860

96

tapping mode atomic force microscopy

581

tensile-bond test

788

tetrasaccharide cellulosic unit

618

texture profile analysis

211

The National Starch and Chemical Co.

766

‘the vinegar plant’

725

theory of mechanical interlocking

783

Theraflu

770

thermal mechanical peeling process

238

Thermamyl

658


Index Terms

Links

thermodynamic adsorption theory

784

thermodynamic incompatibility

421

Thin Strips

770

thixotropic

512

tilted plane method

784

tinzaparin

458

Tirman

479

Tobiko

892

tofu

693

tragacanthin

502

transmission electron microscopy

263

Triaminic

770

Trichoderma reesei

617

Trigonella foenum graecum

231

trimethyl chitosan

871

trimethylamine

893

triple helix formation

581

trisaccharide cellulosic unit

618

trypsin

623

584

664

866

TSX, see tamarind seed xyloglucan tyrosinase

856

tyrosine glucan

856

U Unani

488

uridine diphosphoglucose

726

US Institute of Medicine

53


Index Terms

Links

V van der Waals electrostatic interactions

28

steric interactions

30

vanillin-containing coatings

772

vegetable protein isolates

383

antinutritional factors

413

application in food products

406

potato and green leaves

412

seed protein preparations

408

410

association-dissociation phenomena of legumin- and vicilin-like globulins cereals

392 386

chemical and enzymatic modification of protein products

404

chemical modification

405

enzymatic modification

404


387

cereals

388

legumes

388

oilseeds

389

potatoes, green leaves and fruits

389

choosing best functionality for application classification of storage proteins

406 390

albumins

391

globulins

391

prolamin and glutelins

392


Index Terms

Links

vegetable protein isolates (Cont.) functional properties

399

functional properties for industrial application

401

dough formation

404

foams and emulsions

401

gels and related aspects

402

texturisation of proteins

403

water- and fat-holding capacity

404

green leaves and fruits

387

heat-induced gel formation

403

instability mechanisms of foams and emulsions

402

legumes

384

main processing operations

397

main sources

384

manufacture

394

potato and green leaves processing

399

seed protein extraction

396


412

cereals

414

legumes

413

oilseeds

414

potato and green leaves

414

protein allergenicity

415

oilseeds

386


389

pea proteins

393

potato and green leaf proteins

394

soybean proteins

393


Index Terms

Links

vegetable protein isolates (Cont.) wheat proteins regulatory status

394 415

required functional properties for food applications

407

root vegetables

386

Veis-Aranyi model

423

vicilin

393

vicilin-like proteins

391

Viscofiber

630

viscosity

148

effect of pH

192

effect of salts

192

effect of temperature

193

viscosity troubleshooting

137

vital wheat gluten

416

Vivapure Q Mini-H-column

313

432

637

638

W water gels

178

water vapour permeability

771

Wattle Blossom Model

263

703

Western larch tree, see Larix occidentalis wetting theory

784

wheat, see cereals Wheatpro

411

whey

768

whey protein isolate

769


Index Terms

Links

whey proteins -derived milk protein products composition -enriched products lactalbumin

310 308 312

whey powders and modified whey powders

308

whey protein concentrates

311

whey protein isolates

311

fractionation

312

industrial isolation of protein products

309

physico-chemical characteristics

303

white talha

255

Wilhemly plate

515

311

X xanthan gum

439

Xanthomonas campestris

186

xanthum gum

186

food product applications

195

baked goods, bakery and pie fillings

198

culinary products

200

dairy products

198

dry mixes

201

frozen foods

201

198

functionality and associated applications

197

stabiliser level for salad dressing formulation future trends

200 201


Index Terms

Links

xanthum gum (Cont.) manufacture

187

regulatory status

201

structure primary structure technical data

187 188

compatibility

194

constant viscosity at low pH

194

flow behaviour comparison

192

flow curve of 0.5% xanthan gum solution in standardised tap water

191

gum and media ratio effect on gel strength

196

interactions with galactomannans/ glucomannans

195

pH sensitivity

193

rheology of xanthan gum solution

189

solution stability to acids at ambient temperature

194

structure/property relationship

190

theoretical and observed viscosities

196

viscosity development profile

190

xanthan gum solution preparation

188

XCells Antimicrobial Wound Dressing

735

XCells Cellulose Wound Dressing

735

x-ray diffraction

679

xylanase

677

678


Index Terms

Links

xyloglucan

535

applications in food industry

553

application of low-viscosity tamarind seed gum

556

emulsion stabiliser

554

fat replacement

556

gelling agent

555

ice crystal stabilisation

555

starch modification

555

thickener or stabiliser

553

concentration dependence of viscosity

543

effects on plasma lipids hydrolysed xyloglucan

559

xyloglucan and hydrolysed xyloglucan

559

emulsifying properties of soy proteinpolysaccharide conjugates

555

and epigallocatechin gallate NOESY spectrum

551

estimated molecular characteristic parameters

541

food application of low viscosity TSX

557

food applications

554

frequency and temperature dependence of storage shear modulus

545

gel strength

547

interactions

546

gelation by addition of polyphenols

548

gelation by change of solvent

546


Index Terms

Links

xyloglucan (Cont.) gelation of tamarind seed xyloglucan

551

iodine colour reaction

553

Mark–Houwink–Sakurada plots

540

and native xanthan temperature dependence

552

origin, distribution and preparation

535

other aspects and applications

561

drug delivery systems

562

plant growth and plant defense systems physiological effects

561 558

biological functions

560

carbohydrate metabolism

559

improved lipid metabolism

558

potential linkages with cellulose

536

regulatory status in food industry

557

repeating unit chemical structure

538

rheology and DSC results cooling and subsequent heating

550

heating

549

safety data

557

sol-gel transition temperature diagram

548

structure and fundamental properties

538

chemical structure

538

dilute solution properties

539

molecular weight

539

rheological properties at higher concentrations

542


Index Terms

Links

xyloglucan (Cont.) TSX and LVTSX concentration dependence of steady shear viscosity

556

and xanthan solutions steady shear viscosity

544

xyloglucan endotransglycosylase

561

xylooligosaccharides

664

Xylos

735

681

Y Yariv’s reagent

487

yokan

100

youkan

555

Young’s modulus

731

734

818

Z zein

392

Zisman plots

775


Handbook of Hydrocolloids

Handbook of Hydrocolloids

Hydrocolloids in Food Processing

Hydrocolloids : 2-Volume Set

NATURAL PLANT HYDROCOLLOIDS # 11

Natural Plant Hydrocolloids

Physical Functions of Hydrocolloids (Advances in Chemistry 025)

Oxford American Handbook of Urology (Oxford Handbook)

Handbook of Psychoeducational Assessment: A Practical Handbook

Oxford American Handbook of Urology (Oxford Handbook)

Handbook of Thermoplastic Elastomers (Pdl Handbook)

Handbook of Turbomachinery

Handbook of Electronic Weighing

Lange's Handbook of Chemistry

CRC Handbook of Thermoelectrics

Handbook of Inorganic Chemicals

The handbook of integration

Handbook of photochemistry

Handbook of spatial logics

Handbook of constraint programming

Handbook of Corynebacterium glutamicum

Handbook of algebra

The Handbook of Dramatherapy

Springer Handbook of NanoTechnology

Handbook of ornament

Practical Handbook of Photovoltaics

Lange's Handbook of Chemistry

Handbook of VLSI Microlithography

Handbook of Inorganic Chemicals

Handbook of Hydrocolloids